Live Attenuated Tularemia Vaccines for Protection Against Respiratory Challenge With Virulent F. tularensis subsp. tularensis.

Francisella tularensis is the causative agent of tularemia and a Tier I bioterrorism agent. In the 1900s, several vaccines were developed against tularemia including the killed "Foshay" vaccine, subunit vaccines comprising F. tularensis protein(s) or lipoproteins(s) in an adjuvant formulation, and the F. tularensis Live Vaccine Strain (LVS); none were licensed in the U.S.A. or European Union. The LVS vaccine retains toxicity in humans and animals-especially mice-but has demonstrated efficacy in humans, and thus serves as the current gold standard for vaccine efficacy studies. The U.S.A. 2001 anthrax bioterrorism attack spawned renewed interest in vaccines against potential biowarfare agents including F. tularensis. Since live attenuated-but not killed or subunit-vaccines have shown promising efficacy and since vaccine efficacy against respiratory challenge with less virulent subspecies holarctica or F. novicida, or against non-respiratory challenge with virulent subsp. tularensis (Type A) does not reliably predict vaccine efficacy against respiratory challenge with virulent subsp. tularensis, the route of transmission and species of greatest concern in a bioterrorist attack, in this review, we focus on live attenuated tularemia vaccine candidates tested against respiratory challenge with virulent Type A strains, including homologous vaccines derived from mutants of subsp. holarctica, F. novicida, and subsp. tularensis, and heterologous vaccines developed using viral or bacterial vectors to express F. tularensis immunoprotective antigens. We compare the virulence and efficacy of these vaccine candidates with that of LVS and discuss factors that can significantly impact the development and evaluation of live attenuated tularemia vaccines. Several vaccines meet what we would consider the minimum criteria for vaccines to go forward into clinical development-safety greater than LVS and efficacy at least as great as LVS, and of these, several meet the higher standard of having efficacy ≥LVS in the demanding mouse model of tularemia. These latter include LVS with deletions in purMCD, sodBFt , capB or wzy; LVS ΔcapB that also overexpresses Type VI Secretion System (T6SS) proteins; FSC200 with a deletion in clpB; the single deletional purMCD mutant of F. tularensis SCHU S4, and a heterologous prime-boost vaccine comprising LVS ΔcapB and Listeria monocytogenes expressing T6SS proteins.

Introduction

Francisella tularensis, the causative agent of tularemia, was originally named Bacterium tularense by McCoy and Chapin in 1911, who discovered it as the causative agent of a “plague like disease” prevalent among the ground squirrels in Tulare County, California (McCoy GW, 1912; Francis, 1925). The bacterium was designated as Pasteurella tularensis in 1920's and later renamed Francisella tularensis in honor of the contributions made by Dr. Edward Francis among others (Francis, 1928; Weinberg, 2004; Sjostedt, 2007). Several vaccine strategies were developed in the 1900s against virulent F. tularensis infection, including killed whole cell vaccines, subunit vaccines, and live attenuated homologous vaccines (Wayne Conlan and Oyston, 2007). A killed whole cell vaccine, the earliest vaccine developed against tularemia and referred to as the “Foshay” vaccine (Foshay, 1932; Foshay et al., 1942), was prepared from phenolized liquid culture and was not highly protective against subsequent systemic and aerosol challenge with highly virulent strains of F. tularensis in mice, guinea pigs, rabbits, and humans (Foshay, 1932; Foshay et al., 1942; Kadull et al., 1950; Vanmetre and Kadull, 1959; Eigelsbach and Downs, 1961; Saslaw et al., 1961a,b). Subunit vaccines comprising F. tularensis protein(s) or lipoproteins(s) in an adjuvant formulation also failed to demonstrate strong protective immunity against virulent non-Type A or Type A F. tularensis in animal models (Sjostedt et al., 1992b; Golovliov et al., 1995; Fulop et al., 2001; Conlan et al., 2002). Live attenuated homologous vaccines showed greater promise. The earliest live attenuated homologous tularemia vaccine, Live Vaccine Strain or LVS, derived from a virulent isolate of F. tularensis subsp. holarctica (Type B), was developed by U.S.A. and Russian scientists in the 1950s (Eigelsbach and Downs, 1961). However, LVS retained considerable virulence in animals and provided incomplete protection to humans challenged with F. tularensis subsp. tularensis (Type A) by aerosol, the route of transmission of greatest concern in a bioterrorist attack (Saslaw et al., 1961a; Hornick and Eigelsbach, 1966; Fortier et al., 1991). The fundamental mechanism of LVS attenuation is not fully understood, although pilA and FTT0918 have been identified as contributing to LVS virulence (Salomonsson et al., 2009). The LVS vaccine has not been licensed in the U.S.A., or in the European Union.

Until 2001, few researchers were actively working on vaccine development against tularemia. However, in the wake of the September 11, 2001 terrorist attack on the World Trade Center and the U.S.A. anthrax bioterrorism attack 1 week later, there has been renewed interest in vaccine development against tularemia and other potential biowarfare agents. This has been accompanied by a substantial increase in publications on development of tularemia vaccines, mostly on live attenuated vaccine candidates, including defined mutants of F. tularensis subsp. holarctica (Bakshi et al., 2006, 2008; Pechous et al., 2006, 2008; Li et al., 2007; Sebastian et al., 2007, 2009; Meibom et al., 2008; Sammons-Jackson et al., 2008; Santiago et al., 2009; Jia et al., 2010; Zarrella et al., 2011; Kim et al., 2012; Schmitt et al., 2012; Barrigan et al., 2013; Golovliov et al., 2013; Mahawar et al., 2013; Straskova et al., 2015; Suresh et al., 2015), F. novicida (Pammit et al., 2006; Tempel et al., 2006; Mohapatra et al., 2007; Quarry et al., 2007; Kanistanon et al., 2008; West et al., 2008; Cong et al., 2009; Sanapala et al., 2012; Signarovitz et al., 2012; Chu et al., 2014; Cunningham et al., 2014), and subsp. tularensis (Twine et al., 2005, 2012; Qin et al., 2008, 2009; Conlan et al., 2010; Michell et al., 2010; Shen et al., 2010; Ireland et al., 2011; Rockx-Brouwer et al., 2012; Reed et al., 2014; Santiago et al., 2015), but also on live attenuated heterologous vaccines expressing F. tularensis proteins (Jia et al., 2009; Kaur et al., 2012; Banik et al., 2015) and recombinant LVS vaccines expressing F. tularensis proteins (Jia et al., 2013, 2016). Some of these vaccine candidates have been reviewed elsewhere (Conlan, 2011; Marohn and Barry, 2013; Elkins et al., 2016). Because vaccine efficacy against respiratory challenge with subsp. holarctica or against non-respiratory challenge with subsp. tularensis does not reliably predict vaccine efficacy against respiratory challenge with subsp. tularensis (Conlan, 2011; Marohn and Barry, 2013), as noted the route of transmission and species of greatest concern in a bioterrorist attack, in this review, we focus on live attenuated vaccines that have been tested against respiratory challenge with virulent F. tularensis subsp. tularensis—the SCHU S4 strain originally isolated from a human ulcer in 1941 (Eigelsbach et al., 1951) or FSC033 (Francisella Strain Collection from Swedish Defense Research Agency, Sweden) originally isolated from a squirrel in Georgia (Forsman et al., 1994).

Tularemia and F. tularensis

Tularemia occurs in nature as a fatal bacteremia of various rodents and other animals, such as rabbits, and is transmitted to humans as an accidental infection (Francis, 1925). Depending primarily on the route of transmission, there are several clinical forms of tularemia, including ulceroglandular and glandular tularemia caused by an arthropod bite or skin contact with an infected animal; oculoglandular tularemia caused by direct infection of the eye; oropharyngeal tularemia caused by ingestion of water contaminated by infected rodents or other animals or consumption of under-cooked meat from an infected animal; typhoidal tularemia from any mode of transmission; and pneumonic tularemia caused by inhalation of aerosolized bacteria. Typhoidal and pneumonic tularemia are the most dangerous forms as they carry a high fatality rate−30–60% if untreated (Dennis et al., 2001; Matyas et al., 2007). Because F. tularensis is one of the most pathogenic human pathogens known and can be spread by aerosol transmission to cause highly fatal pneumonic tularemia, it is classified as a Tier 1 select agent of bioterrorism, i.e., among the most likely pathogens to be deliberately used in a bioterrorist attack. In fact, Japan, the U.S.A., and the U.S.S.R. have stockpiled F. tularensis as a bioweapon in the past (Harris, 1992; Christopher et al., 1997; Alibek, 1999). F. tularensis subsp. tularensis (Type A), prevalent in North America, is the most virulent subsp.; intracutaneous challenge or inhalation of as few as 10–50 colony forming units (CFU) (SCHU S4 strain) is able to cause clinical tularemia in humans (McCrumb, 1961; Saslaw et al., 1961a,b). F. tularensis subsp. holarctica (Type B), found in Europe, Asia and North America, is less virulent than subsp. tularensis. Subsp. mediasiatica, found in the Central Asia and the former USSR, is of similar virulence to subsp. holarctica (Sjostedt, 2007). F. novicida, genetically closely related to F. tularensis and frequently referred to as subsp. novicida (Rohmer et al., 2007; Huber et al., 2010), is currently classified as a separate species (Johansson et al., 2010; Kingry and Petersen, 2014). F. novicida shows low virulence in experimental models, occasionally causes disease in immunocompromised individuals, and has been isolated from patients with various clinical entities in the U.S.A., Canada, Australia, and Spain (Bernard et al., 1994; WHO, 2007).

Biology and pathogenesis of experimental tularemia and the host response

F. tularensis is a facultative intracellular pathogen that is capable of infecting multiple types of eukaryotic cells, including macrophages. Using a human macrophage-like cell line (THP-1), Clemens et al. showed that F. tularensis subsp. tularensis SCHU S4 and subsp. holarctica LVS enter human macrophages via a unique complement-dependent process termed looping phagocytosis; then enter a unique fibrillar-coated phagosome; and finally exit the phagosome to multiply freely in the cytoplasm using a Type VI Secretion System (T6SS) (Clemens et al., 2004, 2005, 2015; Clemens and Horwitz, 2007). In addition to the macrophage, F. tularensis can infect alveolar type II epithelial cells, neutrophils, dendritic cells, and others (Metzger et al., 2007). Studies on the pathogenesis of experimental tularemia were mostly conducted in mice and to a lesser extent in Fisher rats and non-human primates (Jemski, 1981; Lyons and Wu, 2007; Hutt et al., 2017). Upon i.d. or aerosol infection, F. tularensis quickly disseminates systemically to spleen, liver, lung, lymph nodes, and bone marrow, and multiplies in these organs (Conlan et al., 2003; Fritz et al., 2014). As with many other intracellular pathogens, F. tularensis does not produce a toxin to cause tissue damage. Instead, F. tularensis damages tissues by invasion and destruction. Multiplication of F. tularensis, especially subsp. tularensis, in the tissues fails to trigger—but rather actively suppresses—innate immune responses in humans, which likely contributes to its enhanced pathogenicity (Bosio et al., 2007; Gillette et al., 2014). Although various immune responses to LVS vaccination and F. tularensis infection have been identified in animal models, correlates of protection are still not known. Both LVS vaccination and subsp. tularensis infection induce antibody responses. In the mouse, LVS vaccination induces F. tularensis antigen specific humoral (antibodies and B cells) and cellular (both CD4+ and CD8+ T cells) immune responses. While T-cell mediated immune responses are important for control of primary Francisella infection or vaccine-induced protection, antibodies may also provide prophylactic and therapeutic protection against pulmonary infection with low virulence F. tularensis, strains (Elkins et al., 2007; Metzger et al., 2007; Cole et al., 2009). Protective immunity induced by natural infection with F. tularensis or vaccination with LVS in humans depends primarily upon cell-mediated Th1-type immune responses, including interferon-gamma (IFN-γ), tumor necrosis factor-alpha (TNF-α), and interleukin-12 (IL-12) (Karttunen et al., 1987; Tarnvik, 1989; Sjostedt et al., 1992a; Ericsson et al., 1994, 2001).

The LVS vaccine in human studies

The LVS vaccine was studied for safety and efficacy in small numbers of individuals in the 1960s. Saslaw et al. showed that individuals vaccinated with LVS intradermally (i.d., via multiple punctures) develop local lesions manifested by erythema (~1 cm in diameter) followed by non-tender papules that fade rapidly with no fever or systemic reactions (Saslaw et al., 1961a). Hornick et al. showed that among persons exposed to aerosolized LVS, 90% of individuals that inhaled 108 LVS exhibited mild typhoidal tularemia and 80% had temperature elevations of >100°F; symptoms and signs were milder when the inhalation dose was reduced to 106 (Hornick and Eigelsbach, 1966). Saslaw et al. further showed that i.d. vaccination of humans with LVS induced incomplete protection (3 of 18 persons developed disease vs. 8 of 10 nonvaccinated controls) against aerosol challenge with 10–53 CFU of subsp. tularensis SCHU S4 strain; in contrast, in a separate part of the study, the Foshay vaccine was not protective as there was no significant difference in the incidence of disease between the vaccinated and unvaccinated groups after aerosol challenge with similar doses of subsp. tularensis SCHU S4 strain (Saslaw et al., 1961a). Hornick and Eigelsbach demonstrated that individuals vaccinated with 106 or 108 CFU LVS by aerosol were well protected (none required antibiotic treatment) against a high dose challenge with aerosolized SCHU S4 (25,000 CFU, 500–2,500 minimum infective doses) 4–6 months post-vaccination. Similarly vaccinated volunteers were better protected than individuals immunized with a lower dose of LVS (104 CFU) by aerosol or vaccinated i.d. by acupuncture; 46% of the latter group required antibiotic treatment vs. 89% of unvaccinated controls (Hornick and Eigelsbach, 1966). Hornick et al. also demonstrated that oral vaccination with LVS provided incomplete protection against aerosol challenge with SCHU S4 (Hornick et al., 1966). However, the i.d. route, but not the aerosol or oral route, has been regularly used for humans in the U.S.A. Saslaw and Carhart found that the greater efficacy of the live LVS vaccine than the Foshay killed vaccine was not related to antibody titers (Saslaw and Carhart, 1961). Recently, a new lot of LVS manufactured under modern GMP conditions has been studied in animals and in two human clinical trials to evaluate its safety, reactogenicity, and immunogenicity (Pasetti et al., 2008; El Sahly et al., 2009; Mulligan et al., 2017). In a Phase I study, Sahly et al. reported that individuals vaccinated with LVS by scarification or subcutaneously (s.c.) frequently experienced ≥grade 2 (interfering with activity) systemic complaints, especially headache and fatigue; many experienced erythema and induration at the injection site of which ~one-third had ≥grade 2 erythema (≥30 mm) and induration (≥15 mm). Of note, some individuals, especially those vaccinated by scarification, developed transient lymphangitis and papular satellite lesions surrounding the infection site. High dose scarification vaccination induced serologic immune responses and scarification and to a lesser extent s.c. vaccination induced high IFN-γ responses (El Sahly et al., 2009). In a Phase II study, Mulligan et al. compared the new lot of LVS to the existing USAMRIID LVS vaccine (Mulligan et al., 2017). They found that both vaccines appeared safe. Injection site reactogenicity was deemed generally mild and similar for the two vaccines; severe vaccine site reactions (erythema or induration >5 cm) occurred in 4.4 and 3.5% of vaccinees administered the new lot and USAMRIID vaccines, respectively. Similar percentages of the vaccinees admimistered the new lot or USAMRIID vaccine experienced severe (2 and 3%, respectively) or moderate (24 and 22%, respectively) systemic reactions. Both vaccines resulted in similar (94%) rates of seroconversion.

Thus, while LVS retains residual toxicity, it has demonstrated substantial albeit incomplete protection in humans against aerosol challenge with virulent subsp. tularensis SCHU S4. Although LVS has not been licensed for use in the U.S.A. and European Union, it is the only vaccine that has been shown to be reasonably safe and efficacious in humans. There is a general consensus that any vaccine that warrants further consideration as a human vaccine needs to be safer than LVS while providing protection comparable to or greater than that provided by LVS against aerosolized fully virulent F. tularensis subsp. tularensis. Because LVS retains significant virulence in animals, has toxicity in humans, and provides incomplete protection against aerosol challenge with SCHU S4, there has been great interest since 2001 in developing alternative vaccines—these are reviewed below and summarized in Tables 1–5. We focus here on vaccines that have been tested against subsp. tularensis SCHU S4 respiratory challenge and compared with LVS for efficacy and virulence.

Table 1

F. tularensis subsp. holarctica mutants: Protection against subsp. tularensis SCHU S4 respiratory challenge.

Vaccinea	Host strain	Vaccine route, dose (CFU)b	Boost (route)	LVS control (route)	Interval (days)c	SCHU S4 challenge route, dose (CFU)	% Survival post-challenge (MST, days)d			References
							Vaccine	LVS	Sham
NUTRIENT METABOLIC MUTANT
LVS ΔpurMCD	BALB/c	i.n., 106	No	Yes (i.n.)	42	i.n., 100	0 (6)	100 (21)	0 (5)	Pechous et al., 2008
						i.n., 2000	0 (5)	0 (7)	0 (5)
	BALB/c	i.n., 106	Yes (i.n.)	Yes (i.n.)	21	i.n., 100	100 (21)	100 (21)	0 (5)	Pechous et al., 2008
						i.n., 2000	33 (17)	33 (11)	0 (5)
OXIDATIVE STRESS RESPONSE MUTANTS
LVS ΔsodBFt	C57BL/6	i.n., 5 × 103	No	Yes (i.n.)	21	i.n., 14	40	0 (12)	0 (7)	Bakshi et al., 2006, 2008
	C57BL/6	i.n., 5 × 102	Yes (i.n.)	Yes (i.n.)	21	i.n., 103	42	0 (15)	0 (6)	Bakshi et al., 2006, 2008
emrA1	C57BL/6	i.n., 106	No	No	21	i.n., 32	0 (8)	ND	0 (6)	Suresh et al., 2015
		i.n., 106	Yes (i.n.)	No	21	i.n., 38	0 (9)	ND	0 (6)	Suresh et al., 2015
		i.d., 106	Yes (i.d.)	No	21	i.n., 17	0 (10)	ND	0 (7)	Suresh et al., 2015
		i.d., 106	Yes (i.n.)	No	21	i.n., 17	0 (10)	ND	0 (7)	Suresh et al., 2015
		i.n., 103	Yes (i.d.)	No	21	i.n., 23	20	ND	0 (6)	Suresh et al., 2015
		i.d., 103	Yes (i.n.)	No	21	i.n., 24	20	ND	0 (6)	Suresh et al., 2015
ΔdsbA/FSC200	BALB/c	i.n., 102	No	No	28	i.n., 100	0	ND	0 (5)	Straskova et al., 2015
		i.n. 103	No	No	28	i.n., 100	0	ND	0 (5)	Straskova et al., 2015
		i.n., 104	No	No	28	i.n., 100	20	ND	0 (5)	Straskova et al., 2015
		i.n., 105	No	No	28	i.n., 100	30	ND	0 (5)	Straskova et al., 2015
		i.n., 106	No	No	28	i.n., 100	50	ND	0 (5)	Straskova et al., 2015
HEAT SHOCK PROTEIN MUTANTS
LVS ΔclpB	BALB/c	i.d., 105	No	No	42	i.n. 40	0 (~12)	ND	0 (5)	Golovliov et al., 2013
FSC200 ΔclpB	BALB/c	i.d., 105	No	Yes (i.d.)	42	i.n. 86	40	0	0 (5)	Golovliov et al., 2013
CAPSULAR AND MEMBRANE MUTANTS
LVS ΔcapB	BALB/c	i.d., 106	No	Yes (i.d.)	42	Aero., 10	0 (10)	67 (16)	0 (5)	Jia et al., 2010
		i.n., 105	No	Yes (i.n.)	42	Aero. 10	100 (21)	100 (21)	0 (5)	Jia et al., 2010
rLVS ΔcapB/IglA	BALB/c	i.d., 106	No	Yes (i.d.)	42	Aero., 10	50 (16)	63 (17)	0 (5)	Jia et al., 2013
rLVS ΔcapB/IglC	BALB/c	i.d., 106	No	Yes (i.d.)	42	Aero., 10	40 (14)	63 (17)	0 (5)	Jia et al., 2013
rLVS ΔcapB/IglABC	BALB/c	i.d., 106	No	Yes (i.d.)	42	i.n., 16–31	0	50	0 (4)	Jia et al., 2016
	BALB/c	i.d., 106	Yes (i.d.)	Yes (i.d.)	42	i.n., 10	50	50-75	0 (4)	Jia et al., 2018
	BALB/c	i.n., 106	Yes (i.n.)	Yes (i.d.)	42	i.n., 6-10	83-100	50-75	0 (4)	Jia et al., 2018
LVS::Δwzy	BALB/c	i.n., 3.5 × 106	Yes (i.n.)	Yes (i.n.)	28	i.n., 8	84	100	0 (6)	Kim et al., 2012
LVS::wbtA-OPS-TT*	BALB/c	i.n., 1.5 × 107	Yes (i.n.)	No	28	i.n., 10	40 (15)	ND	20 (7)	Sebastian et al., 2009
LVS::ΔwbtA	BALB/c	i.n., 3.7 × 106	Yes (i.n.)	Yes (i.n.)	28	i.n., 8	0	100	0 (6)	Kim et al., 2012
FTL_0057	BALB/c	i.n., 107	No	No	30	i.n., 100	100	ND	0 (6)	Mahawar et al., 2013
FTL_0325	BALB/c	i.n., 107	No	No	30	i.n., 100	100	ND	0 (6)	Mahawar et al., 2013
OTHER MUTANTS
LVS FTL0552(pmrA)	BALB/c	i.n., 105	No	No	30	i.n., 100	30	ND	0 (6)	Sammons-Jackson et al., 2008
	BALB/c	i.n., 105	Yes (i.n.)	No	30	i.n., 100	40	ND	0 (6)	Sammons-Jackson et al., 2008
	C57BL/6	i.n., 104	No	No	30	i.n., 100	0 (9)	ND	0 (7)	Sammons-Jackson et al., 2008
	C57BL/6	i.n., 104	Yes (i.n.)	No	30	i.n., 100	0 (16)	ND	0 (7)	Sammons-Jackson et al., 2008
FTL_0291	BALB/c	i.n., 107	No	No	30	i.n., 100	100	ND	0 (6)	Mahawar et al., 2013
FTL_0304	BALB/c	i.n., 107	No	No	30	i.n., 100	0 (12)	ND	0 (6)	Mahawar et al., 2013

Vaccine:

, animals vaccinated simultaneously with LVS::wbtA and OPS-TT [LVS O-polysaccharide (OPS) conjugated with–tetanus toxoid (TT)].

Vaccine route, dose: i.n., intranasal; i.d., intradermal.

Interval: Interval between the only or the last vaccination and challenge.

% Survival: % survival post-challenge in animals immunized with the vaccine candidate (vaccine), LVS control (LVS), or PBS or unvaccinated control (Sham); MST, Mean/Median Survival Time; ND, not determined.

Live attenuated subsp. holarctica vaccine candidates

Various mutant strains of subsp. holarctica, mainly in the background of LVS, have been developed, including mutants that have a lesion in a pathway or gene involved in nutrient metabolism (purMCD), response to oxidant stress (sodB, emrA1), the heat shock response (clpB), putative capsular synthesis (capB), membrane integrity (FTL_0325, FTL_0057, wbtA, wzy), transcription (mglA), disulfide bond formation (dsbA), and other functions (Bakshi et al., 2006, 2008; Pechous et al., 2006, 2008; Meibom et al., 2008; Sebastian et al., 2009; Jia et al., 2010, 2013; Kim et al., 2012; Barrigan et al., 2013; Golovliov et al., 2013; Mahawar et al., 2013; Straskova et al., 2015; Suresh et al., 2015). Some of these strains have demonstrated significant attenuation by the intranasal (i.n.) route, and importantly, provided immune protection against respiratory challenge with virulent subsp. tularensis SCHU S4 strain (Table 1). The SCHU S4 strain of F. tularensis subsp. tularensis is used almost exclusively in vaccine testing. Of note, although the virulence of LVS in BALB/c mice is similar to that in C57BL mice, with an estimated LD50 in both strains of <103 CFU by the i.n. route, < 101 CFU by the intraperitoneal (i.p.) route, and >107 CFU by the intradermal (i.d.) route (Saslaw et al., 1961a; Hornick and Eigelsbach, 1966; Fortier et al., 1991; Jia et al., 2009), the protective immunity induced by LVS is different in these two mouse strains (Chen et al., 2003). BALB/c mice immunized with LVS are protected against systemic challenge with both subsp. tularensis and subsp. holarctica strains; C57BL mice immunized with LVS are protected against systemic challenge with only the subsp. holarctica strain (Chen et al., 2003).

Nutrient metabolic mutant

Pechous et al. constructed an LVS mutant with a deletion in the purMCD purine biosynthetic locus, LVS ΔpurMCD, by allelic exchange (Pechous et al., 2006), and complemented the ΔpurMCD strain in trans with wild type purMCD. The authors showed that the LVS ΔpurMCD mutant is defective for growth in medium containing limiting concentrations of purines and is defective for intra-macrophage growth, as it escapes from the phagosome but fails to replicate in the cytosol. The ΔpurMCD mutant is significantly attenuated in BALB/c mice with an LD50 >5 × 106 by the i.p. route (vs. < 101 CFU for LVS). 100% of BALB/c mice immunized i.p. with 5 × 104-5 × 106 CFU of the LVS ΔpurMCD mutant and challenged 21 days later i.p. with parental LVS (5 × 101-5 × 103) survived the challenge, while 40% of naïve mice survived the challenge (Pechous et al., 2006). The authors furthered tested the efficacy of LVS ΔpurMCD, with or without boosting, against respiratory challenge with SCHU S4 and compared it with LVS. In contrast to the result after challenge of the immunized mice with LVS i.p., mice immunized i.n. once with LVS ΔpurMCD were not protected (0% survival) against i.n. challenge with SCHU S4, similar to sham-immunized mice, whereas mice immunized i.n. once with LVS had 100% survival. However, the protection was increased to the levels induced by LVS following a homologous booster vaccination (Table 1, Nutrient metabolic mutant) (Pechous et al., 2008). These studies underscore the fact that protection against challenge with subsp. holartica LVS is not predictive of protection against challenge with subsp. tularensis SCHU S4, especially when the vaccination and challenge routes are different, in this case i.p/i.p. vs. i.n./i.n.

Oxidative stress response mutants

Several oxidant mutants of LVS have been reported (Lenco et al., 2005; Bakshi et al., 2006, 2008; Buchan et al., 2009; Melillo et al., 2009; Honn et al., 2012, 2017; Ma et al., 2014; Suresh et al., 2015; Saha et al., 2017) among which LVS mutants with a point mutation in sodB (FTL_1791), encoding an iron superoxide dismutase (sodBFt), with a transposon insertion in a putative gene for the EmrA1 (FTL_0687) secretion protein (emrA1), or with a deletion in dsbA, encoding a disulfide oxidoreductases protein family homolog (ΔdsbA/FSC200), have been tested in mice for their efficacy against respiratory challenge with SCHU S4 (Bakshi et al., 2006, 2008; Straskova et al., 2015; Suresh et al., 2015). Both sodBFt and emrA1 LVS mutants are sensitive to oxidant stress and are more attenuated than the parental LVS in mice; C57BL/6 and BALB/c mice infected i.n. with 1 × 104 CFU of the sodBFt mutant of LVS had 83 and 60% survival, respectively, while C57BL/6 and BALB/c mice infected i.n. with 1 × 104 CFU parental LVS had 8.3 and 0% survival, respectively (Bakshi et al., 2006). C57BL/6 mice immunized i.n. with 5 × 103 sodBFt mutant and 21 days later challenged i.n. with 14 CFU SCHU S4 had 40% survival, significantly greater than that of naïve mice (0% survival) and mice immunized i.n. with 5 × 103 LVS (0% survival). The protection was similar following administration of a homologous booster vaccination (42% survival) against i.n. challenge with 103 CFU of SCHU S4 (Table 1, Oxidative stress response mutants) (Bakshi et al., 2008). It is noted that the i.n. vaccination doses for the sodBFt mutant and LVS were both close to the LD50 i.n. and the interval between the last immunization and challenge was only 21 days.

The emrA1 mutant of LVS is more attenuated than the sodBFt mutant of LVS in mice, with an LD50 > 106 i.n. in C57BL/6 mice (Ma et al., 2014). However, mice immunized with 1 x106 emrA1 and challenged 21 days later i.n. with 32 CFU of the heterologous subsp. tularensis SCHU S4 strain had 0% survival; mice homologously primed-boosted with 1 × 106 emrA1 via the i.n. or the i.d. route or both routes alternately (i.d./i.n,. or i.n./i.d.) and challenged 21 days later had 0–20% survival, similar to naïve mice (Table 1, Oxidative stress response mutants). It is noted that mice immunized with emrA1 had 100% survival after i.n. challenge with the homologous parental LVS strain at doses up to 1 × 108 CFU LVS (Suresh et al., 2015). Thus, the vaccine was poorly protective against SCHU S4 but highly protective against LVS. These results suggest that over attenuation of LVS resulted in a significant reduction in protective immunity. Importantly, these results once again show that efficacy against respiratory challenge with subsp. holartica LVS does not predict efficacy against respiratory challenge with subsp. tularensis SCHU S4 (see Summary and Discussion).

The dsbA mutant of FSC200 (a fully virulent Type B strain genetically similar to LVS, with LD100 < 5 CFU i.d. and i.p. in mice), ΔdsbA/FSC200, administered i.n. has also shown dose-dependent protection against i.n. challenge with SCHU S4 (Table 1, Oxidative stress response mutants) (Straskova et al., 2015).

Heat shock protein mutants

Several F. tularensis Type B (LVS and FSC200) mutants defective in heat shock chaperone protein ClpB, which is involved in the response to oxidative, ethanol, and acid stresses, have been reported (Meibom et al., 2008; Golovliov et al., 2013). LVS ClpB (FTL_0094) has 98–100% identity to ClpB in other F. tularensis strains (Meibom et al., 2008). The clpB mutant strains derived from subsp. holarctica LVS and FSC200 and subsp. tularensis SCHU S4 are attenuated when delivered by i.d., i.p., or oral routes; they have been tested as vaccine candidates against respiratory challenge with SCHU S4 (Meibom et al., 2008; Conlan et al., 2010; Shen et al., 2010; Twine et al., 2012; Golovliov et al., 2013; Ryden et al., 2013). Specifically, the LD50 for the LVS ΔclpB (transposon insertional mutant) is >107 CFU i.p. in BALB/c mice (vs. < 101 CFU for LVS) and the LD50 for FSC200 ΔclpB (deletional mutant) is >1 × 105 CFU i.n. for BALB/c mice (vs. ~103 CFU for LVS); however, FSC200 ΔclpB replicated to higher numbers at the intradermal vaccination site and was more lethal than LVS in SCID mice (Meibom et al., 2008; Golovliov et al., 2013). C57BL/6J (B6) mice immunized i.n. with 5 × 104 LVS ΔclpB and challenged 28 or 120 days later with 5 × 103 parental LVS i.n. (~5 LD50) had 100% survival, the same as mice immunized with 5 × 102 LVS i.n.; all naïve mice died by day 7 (Barrigan et al., 2013). In a separate study, BALB/c mice immunized i.d. with 105 CFU LVS ΔclpB and challenged 6 weeks later i.n. with 40 CFU SCHU S4 had 0% survival (Golovliov et al., 2013). BALB/c mice immunized i.d. with 105 CFU FSC200 ΔclpB and challenged 6 weeks later i.n. with 86 CFU SCHU S4 had ~40% survival vs. 0% for mice immunized i.d. with LVS (Golovliov et al., 2013). Both FSC200 ΔclpB and LVS ΔclpB mutants were generally less protective than a SCHU S4 ΔclpB mutant against i.n. challenge with SCHU S4 (Table 1, Table 3, Heat shock protein mutants), although the latter strain has only a single deletional mutation and thus presents safety issues (see Summary and Discussion).

Putative capsular and membrane mutants

F. tularensis Type B mutants defective in genes involved in putative capsular and membrane synthesis are highly attenuated in mice, including LVS mutants defective in capBCA (FTT0806, FTT0805, and FTT0798, respectively), wzy, wbtA, FTL_0057, and FTL_0325 (Table 1, Capsular and membrane mutants) (Sebastian et al., 2007; Su et al., 2007, 2011; Weiss et al., 2007; Jia et al., 2010; Michell et al., 2010; Kim et al., 2012; Mahawar et al., 2013). We have constructed and characterized a defined LVS mutant with an antibiotic resistance marker-free deletion in capB (FTL_1416) (LVS ΔcapB) as a vaccine candidate and shown that LVS ΔcapB is resistant to serum killing, out-competed for growth by its parental LVS in infected human macrophage cells, and significantly more attenuated (>10,000-fold) than LVS administered i.n. in mice (Jia et al., 2010). BALB/c mice immunized with LVS ΔcapB i.n. or i.d. develop humoral and cellular immune responses comparable to LVS and induce full protection (100% survival) against i.n. challenge 4 or 8 weeks later with the parental LVS vaccine (~5 LD50). Most importantly, while the vaccine was poorly protective when administered i.d., mice immunized with LVS ΔcapB i.n. were highly protected (100% survival) against an aerosol challenge 6 weeks later with 10 × LD50 F. tularensis SCHU S4 (Table 1, Capsular and membrane mutant) (Jia et al., 2010). In subsequent studies, we constructed several rLVS ΔcapB strains over-expressing T6SS proteins IglA (rLVS ΔcapB/iglA) or IglC (rLVS ΔcapB/iglC) or a fusion protein comprising immunoprotective domains of IglA, IglB, and IglC (rLVS ΔcapB/iglABC) and evaluated their capacity to protect against i.n. challenge (more consistent route than aerosol challenge) with F. tularensis SCHU S4. BALB/c mice immunized once i.d. with rLVS ΔcapB/iglC or rLVS ΔcapB/iglA had a significantly greater survival rate (40 and 50%, respectively) than mice immunized with the parental LVS ΔcapB vector (0% survival, p = 0.09 and 0.01, respectively), which was not significantly different from that of the LVS-immunized mice (63% survival) (Table 1, Capsular and membrane mutant) (Jia et al., 2013). In separate studies, mice homologously primed-boosted with rLVS ΔcapB/iglABC i.n. three times at Weeks 0, 4, and 8 or twice at Weeks 4 and 8 and challenged i.n. at Week 14 with a lethal dose of SCHU S4 had 83–100% survival—greater than LVS i.d. vaccination—while all the naïve mice died at day 4 post-challenge. Mice homologously primed-boosted i.d. with rLVS ΔcapB/iglABC twice or three times had survival equivalent to LVS-immunized mice (Table 1, Capsular and membrane mutants) (Jia et al., 2016, 2018).

Kim et al. constructed wzy (O-antigen polymerase) (LVS::Δwzy) and wbtA (LVS::ΔwbtA) deletional mutants of LVS; both were significantly attenuated in mice (Kim et al., 2012). BALB/c mice immunized i.n. with LVS::Δwzy, but not with LVS::ΔwbtA, were highly protected against i.n. challenge 4 weeks later with 8 CFU SCHU S4, similar to LVS i.n. immunized mice (Table 1, Capsular and membrane mutants) (Kim et al., 2012). Mahawa et al. developed LVS mutants defective in a conserved hypothetical membrane protein (FTL_0057) or in an outer membrane protein A-like family protein (FTL_0325). BALB/c mice immunized i.n. with FTL_0057 or FTL_0325 mutants of LVS were highly protected against i.n. challenge with SCHU S4; however, their efficacy relevant to LVS was not studied (Table 1, Capsular and membrane mutants) (Mahawar et al., 2013).

Other subsp. holarctica mutants

Subsp. holarctica LVS mutants deficient in FTL_0552 (a transcriptional response regulation gene, pmrA), FTL_0291, or FTL_0304 also have shown attenuated phenotypes and protective efficacy against i.n. challenge with SCHU S4 in murine models. However, these mutants were not compared for efficacy with the parental LVS vaccine (Table 1, Other mutants) (Sammons-Jackson et al., 2008; Mahawar et al., 2013).

Live attenuated F. novicida vaccine candidates

F. novicida vaccine candidates have been constructed by deleting genes involved in the purine biosynthesis pathway (purA and purF), the T6SS (iglB, iglC, pdpB, and iglD), the response regulator (pmrA), or in other activities. A complete list of the F. novicida mutants can be found in a review article written by Pechous et al. (2009). However, only a few of the F. novicida mutants, including mutants with a deletion in purF, purA, iglB, iglD, or pmrA, have been tested against challenge with virulent SCHU S4, and even fewer against respiratory challenge with SCHU S4. In one study, BALB/c mice immunized i.p., but not s.c., with F. novicida U112ΔpurF::cm were partially protected against i.p. challenge with the homologous U112 strain, but not against challenge with the heterologous SCHU S4 strain; a similar mutant, U112ΔpurA::cm, was not protective against either U112 or SCHU S4 challenge (Quarry et al., 2007). Two F. novicida U112 iglB deletional mutants, U112ΔiglB and U112ΔiglB::fljB (expressing one domain D of the Salmonella typhimurium FljB flagellin, reportedly a TLR5 agonist), administered orally, have been shown to partially protect against i.n. or intratracheal (i.t.) challenge with SCHU S4 in mice and Fisher rats; however, efficacy was not compared with LVS (Table 2; Cong et al., 2009; Signarovitz et al., 2012; Cunningham et al., 2014). An F. novicida mutant with a deletion in iglD (Fn IglD), although not protective in a murine model of tularemia, has demonstrated protection against i.t. challenge with SCHU S4 in the more resistant Fisher rat model and in the non-human primate model of tularemia (see below for details) (Chu et al., 2014). Another F. novicida mutant with a deletion in an orphan response regulator gene pmfA was protective against homologous U112 but not against heterologous SCHU S4 challenge (Table 2; Mohapatra et al., 2007). Other studies also have shown that F. novicida and its derivative mutants can induce protective immunity against homologous respiratory challenge with wild-type F. novicida; however, these mutants have not been shown capable of inducing protection against respiratory challenge with subsp. tularensis in murine models of pneumonic tularemia by traditional i.d. or i.n. routes (Pammit et al., 2006; Sanapala et al., 2012).

Table 2

F. novicida mutants: Protection against F. tularensis subsp. tularensis challenge.

Vaccine	Host straina	Vaccine route, dose (CFU)b	Boost (route)	LVS control (route)	Interval (days)c	SCHU S4 challenge route, dose (CFU or LD50)d	% Survival post-challenge (MST, days)e			References
							Vaccine	LVS	Sham
U112	BALB/c	i.d., 100	No	Yes (i.d.)	56	Aerosol, 10§	0 (5)	0 (6)	0 (5)	Shen et al., 2004
U112	BALB/c	i.d., 100	No	Yes (i.d.)	56	i.d., 350§	0 (5)	100 (>21)	0 (6)
U112	Rats	i.t., 107	No	No	30	i.t., 25 LD50	100	ND	0 (10)	Signarovitz et al., 2012
		p.o., 107	No	No	30	i.t., 25 LD50	50	ND	0 (10)	Signarovitz et al., 2012
ΔiglB(KKF235)	C57BL/6	p.o., 103	No	No	21	i.n., 25	67	ND	0 (6)	Cong et al., 2009
	C57BL/6	p.o., 103	No	No	21	i.n., 50	10	ND		Cong et al., 2009
	C57BL/6	p.o., 103	Yes (p.o.)	No	21	i.n., 52	40	ND		Cong et al., 2009
ΔiglB	Rats	i.t., 107	No	No	30	i.t., 1.25 × 104*	50	ND	0 (10)	Signarovitz et al., 2012
		p.o., 107	No	No	30	i.t., 1.25 × 104*	50	ND	0 (10)	Signarovitz et al., 2012
ΔiglB::fljB	BALB/c	p.o., 107	No	No	30	i.t., 1.25 × 104*	83	ND		Cunningham et al., 2014
	Rats	p.o., 107	No	No	30	i.t., 1.25 × 104*	88	ND		Cunningham et al., 2014
Fn iglD	BALB/c	i.n., ~109	No	No	30	i.n., 103	0	ND	0	Chu et al., 2014
	Rats	p.o., 107	No	No	30	i.t., 104	83	ND	17	Chu et al., 2014
	Rats	i.t., 105	No	No	30	i.t., 104	100	ND	25	Chu et al., 2014
	Rats	i.t., 107	No	No	30	i.t., 104	83	ND	25	Chu et al., 2014
	NHP	t.b., 108	No	Yes (s.c.)	30	Aerosol, (2,500–5,000)	83	100	0 (8)	Chu et al., 2014
ΔpmrA	BALB/c	i.n. (106)	No	No	35	i.n., 100	Not protected	ND	ND	Mohapatra et al., 2007

Host strain: Mice: BALB/c or C57BL/6 mice; Rats: Fisher rats; NHP: non-human primates, cynomolgus macaques.

Vaccine route: intranasal (i.n.); oral (p.o.); intratracheal (i.t.); via bronchoscopy (t.b.).

Interval: interval between the only or the last vaccination and challenge.

SCHU S4 challenge route (dose, CFU of LD50):

challenged with subsp. tularensis FSC 033 strain; *,1.25 × 10.

% Survival post-challenge: % survival post-challenge in animals immunized with the vaccine candidate (vaccine), LVS control (LVS), or PBS or unvaccinated control (Sham). MST, mean/median survival time. ND; not determined.

T6SS mutant

The Francisella pathogenicity island (FPI) proteins, including IglD, are required for bacterial phagosome escape, intracellular replication, and virulence, and are components of a T6SS apparatus (Clemens et al., 2015). Chu et al. reported on the protective immunity induced by iglD deletion mutants of subsp. tularensis (Ftt iglD) and F. novicida (Fn iglD) in murine, Fischer rat, and non-human primate models of pneumonic tularemia (Chu et al., 2014). Ftt iglD and Fn iglD are defective for intramacrophage replication and attenuated in mice (the LD50 for Fn iglD is 9.7 × 108 CFU i.n. in BALB/c mice vs. ~103 CFU for LVS). Mice immunized i.n. with Fn iglD were fully protected against subsequent homologous challenge with 103 CFU of the parental F. novicida U112 strain; however, mice immunized i.n. with Fn iglD or Ftt iglD were not protected against respiratory challenge with the heterologous subsp. tularensis SCHU S4 strain. Arguing that the mouse may be too sensitive to tularemia, Chu et al. evaluated the Fn iglD vaccine in the Fischer rat, an animal model that has been shown to be more resistant to various Francisella subspecies than mice and non-human primates. Fischer rats vaccinated with Fn iglD orally or i.t. and challenged i.t. 30 days later with subsp. tularensis SCHU S4 had 83–100% survival post-challenge vs. 17–25% survival post-challenge for naïve rats. Of note, Fn iglD was not compared with LVS for efficacy in the murine and rat models. Cynomolgus macaques vaccinated with 108 CFU Fn iglD via bronchoscopy and challenged via head-only aerosol inhalation 30 days later with ~2,500–5,000 CFU SCHU S4 had 83% survival, somewhat less than those immunized s.c with 108 CFU LVS (100% survival); mock vaccinated animals died 7–13 days post-challenge (Table 2; Chu et al., 2014).

Live attenuated subsp. tularensis vaccine candidates

Because subsp. tularensis and subsp. holarctica differ in genetic organization, antigen expression, and disease pathogenesis, it was hypothesized that attenuated mutants on the background of subsp. tularensis may offer better protection against respiratory challenge with the parental subsp. tularensis than mutants derived from subsp. holarctica (Conlan et al., 2003; Wu et al., 2005). Thus, a series of mutants have been generated in the SCHU S4 background with mutations previously shown to attenuate LVS and tested in murine, rabbit, and non-human primate models of pneumonic tularemia (Twine et al., 2005, 2012; Pechous et al., 2008; Qin et al., 2008, 2009; Conlan et al., 2010; Michell et al., 2010; Shen et al., 2010; Rockx-Brouwer et al., 2012; Reed et al., 2014; Santiago et al., 2015). Summarized below are some SCHU S4 mutants that have been tested against respiratory SCHU S4 challenge.

Nutrient metabolic mutants

Based on the capacity of the attenuated LVS ΔpurMCD mutant to induce protective immunity, Pechous et al. generated a defined subsp. tularensis SCHU S4 ΔpurMCD mutant and showed that it is significantly more attenuated in mice when delivered by the i.d. (LD50 > 106 CFU) and i.n. (LD50 > 106 CFU) routes than its parental SCHU S4 strain (LD50 < 10 CFU i.n. or i.d.) (Pechous et al., 2008). However, mice immunized i.n. with SCHU S4 ΔpurMCD had tissue damage in the lung and were protected no better than mice vaccinated with LVS or with an analogous LVS ΔpurMCD mutant. BALB/c mice immunized once i.n. with 104 CFU SCHU S4 ΔpurMCD, 106 CFU LVS ΔpurMCD or 102 CFU LVS and challenged 42 days later i.n. with 100 CFU SCHU S4 had 14, 0, and 100% survival, respectively; mice immunized twice i.n. with the same vaccines had 71, 100, and 100% survival after i.n. challenge with 100 CFU SCHU S4 (Results for SCHU S4 mutant and LVS shown in Table 3, Nutrient metabolic mutants) (Pechous et al., 2008); thus homologous i.n. boosting substantially improved the efficacy of the SCHU S4 ΔpurMCD vaccine. Several other SCHU S4 mutants that are deficient in nutrient metabolic enzymes have also been tested against respiratory challenge with SCHU S4 in a murine or rat model (Table 3, Nutrient metabolic mutants) (Reed et al., 2014; Santiago et al., 2015).

Table 3

F. tularensis subsp. tularensis SCHU S4 mutants: Protection against SCHU S4 respiratory challenge.

Vaccine	Host straina	Vaccine route, dose (CFU)	Boost (route)	LVS control (route)	Interval (days)b	SCHU S4 challenge route, dose (CFU or LD50)c	% Survival post-challenge (MST, days)d			References
							Vaccine	LVS	Sham
NUTRIENT METABOLIC MUTANTS
ΔpurMCD	BALB/c	i.n., 104	No	Yes (i.n.)	42	i.n., 100	14 (11)	100 (21)	0 (5)	Pechous et al., 2008
		i.n., 104	No	Yes (i.n.)	42	i.n., 2000	0 (6)	0 (7)	0 (5)	Pechous et al., 2008
		i.n., 104	Yes (i.n.)	Yes (i.n./i.n.)	21	i.n., 100	71 (18)	100 (21)	0 (5)	Pechous et al., 2008
		i.n., 104	Yes (i.n.)	Yes (i.n./i/n.)	21	i.n., 2000	0 (7)	33 (11)	0 (5)	Pechous et al., 2008
		i.d., 101−6	No	No	21	i.n., 500	0 (6-8)	ND	0 (6)	Pechous et al., 2008
		i.n., 101−6	No	No	21	i.n., 500	0 (6-11)	ND	0 (6)	Pechous et al., 2008
ΔFTT1019c (guaA)	C57BL/6	i.n., 7 × 105	No	No	28	i.n., 100	0 (4)	ND	0 (4)	Santiago et al., 2015
ΔFTT1317c (guaB)	C57BL/6	i.n., 1 × 109	No	No	28	i.n., 95	0 (6)	ND	0 (4)	Santiago et al., 2015
		i.n., 6 × 107	Yes (i.n.)	No	28	i.n., 100	0 (4)	ND	0 (4)	Santiago et al., 2015
ΔFTT1019c, ΔFTT1317c (guaA, guaB)	C57BL/6	i.n., 1 × 108	Yes (i.n.)	No	28	i.n., 100	0 (4)	ND	0 (4)	Santiago et al., 2015
ΔguaBA	Rabbits	i.d., 109	No	Yes (i.d.)	30	Aero., 40 LD50	27 (7)*	0 (7)	0 (5)	Reed et al., 2014
ΔaroD	Rabbits	i.d., 109	No	Yes (i.d.)	30	Aero., 40 LD50	36 (7)*	0 (7)	0 (5)	Reed et al., 2014
HEAT SHOCK PROTEIN MUTANTS
ΔclpB	BALB/c	i.d., 105	No	Yes (i.d.)	42	Aero., 20	60 (28)	0 (8)	0 (5)	Conlan et al., 2010
	BALB/c	i.d., 105	Yes (p.o.)	Yes (i.d./p.o)	42	Aero., 20	20 (11)	0 (8)	0 (5)	Conlan et al., 2010
	C3H/HeN	i.d., 105	No	Yes (i.d.)	42	Aero., 20	0 (10)	0 (11)	0 (5)	Conlan et al., 2010
	C3H/HeN	i.d., 105	Yes (p.o.)	Yes (i.d./p.o)	42	Aero., 20	0 (16)	0 (7)	0 (6)	Conlan et al., 2010
	BALB/c	p.o., 108	No	Yes (p.o.)	42	Aero., 20	40 (16)	0 (5)	0 (5)	Conlan et al., 2010
	BALB/c	p.o., 108	Yes (p.o.)	Yes (p.o./p.o)	42	Aero., 20	20 (11)	0 (7)	0 (5)	Conlan et al., 2010
	C3H/HeN	p.o., 108	No	Yes (p.o.)	42	Aero., 20	0 (12)	0 (5)	0 (5)	Conlan et al., 2010
	C3H/HeN	p.o., 108	Yes (p.o.)	Yes (p.o./p.o)	42	Aero., 20	60 (28)	0 (7)	0 (5)	Conlan et al., 2010
	BALB/c	i.d., 105	No	Yes (i.d.)	42	i.n., 10	100	30	0 (~5)	Shen et al., 2010
	BALB/c	i.d., 105	No	Yes (i.d.)	42	i.n., 100	80	0	0 (~5)	Shen et al., 2010
	BALB/c	i.d., 105	No	Yes (i.d.)	42	i.n., 1000	20	0	0 (~5)	Shen et al., 2010
	BALB/c	i.d., 105	No	No	42	i.n., 100	~75	ND	0 (~5)	Twine et al., 2012
	C57BL/6	i.d., 105	No	No	42	i.n., 100	0	ND	0 (5)	Twine et al., 2012
	BALB/c	i.d., 103	No	No	42	i.n., 105	~100	ND	0 (5)	Golovliov et al., 2013
	BALB/c	i.d., 105	No	No	42	i.n., 105	~80	ND	0 (5)	Golovliov et al., 2013
	BALB/c	i.d., 107	No	No	42	i.n., 105	~60	ND	0 (5)	Golovliov et al., 2013
	BALB/c	i.d., 105	No	No	42	i.n., 40	100	ND	0 (~5)	Golovliov et al., 2013
ΔclpBΔcapB	BALB/c	i.d., 107	No	Yes (i.d.)	42	Aero., 100	≤ 20	0	ND	Golovliov et al., 2013
CAPSULAR MUTANT
ΔFTT0918ΔcapB	BALB/c	i.d., 103	No	Yes (i.d.)	42	Aero., 2	40 (8)	0 (8)	0 (5)	Conlan et al., 2010
		i.d., 103	Yes (p.o.)	Yes (i.d./p.o)	42	Aero., 2	0 (8)	0 (8)	0 (5)	Conlan et al., 2010
		p.o., 108	No	Yes (p.o.)	42	Aero., 2	0 (5)	0 (5)	0 (5)	Conlan et al., 2010
		p.o., 108	Yes (p.o.)	Yes (i.d./p.o.)	42	Aero., 2	0 (8)	0 (7)	0 (5)	Conlan et al., 2010
	C3H/HeN	i.d., 103	No	Yes (i.d.)	42	Aero., 20	0 (5)	0 (11)	0 (5)	Conlan et al., 2010
		i.d., 105	Yes (p.o.)	Yes (i.d./p.o.)	42	Aero., 20	50 (17)	0 (7)	0 (6)	Conlan et al., 2010
		p.o., 108	No	Yes (p.o.)	42	Aero., 20	0 (5)	0 (5)	0 (5)	Conlan et al., 2010
		p.o., 108	Yes (p.o.)	Yes (p.o./p.o.)	42	Aero., 20	0 (5)	0 (7)	0 (6)	Conlan et al., 2010
LIPOPROTEIN MUTANTS
ΔFTT1103	C57BL/6	i.n., 3 × 107	No	No	32	i.n., 68	100	ND	0 (5)	Qin et al., 2009
		i.n., 1 × 108	No	No	32	i.n., 37	100	ND	0 (5)	Qin et al., 2009
		i.n., 3 × 108	No	No	32	i.n., 68	50 (18)	ND	0 (5)	Qin et al., 2009
	BALB/c	i.n., 1 × 108	No	No	33	i.n., 95	75 (21)	ND	0 (5)	Qin et al., 2009
ΔFTT1103(fipB)	Rabbits	i.d., 109	No	Yes (i.d.)	30	Aero., 40 LD50	0 (6)	0 (7)	0 (5)	Reed et al., 2014
OTHER MUTANTS
ΔFTT0918	BALB/c	i.d., 105	No	Yes (i.d.)	63	Aero., 10*	33 (15)	0 (7)	0 (5)	Twine et al., 2005
ΔiglC	BALB/c	i.d., 107	No	Yes (i.d.)	63	Aero., 10*	0 (6)	0 (7)	0 (5)	Twine et al., 2005
ΔiglC	BALB/c	i.d., 105	No	Yes (i.d.)	42	Aero., 20	0 (6)	0 (8)	0 (5)	Conlan et al., 2010
	BALB/c	p.o., 108	No	Yes (p.o.)	42	Aero., 20	0 (5)	0 (5)	0 (5)	Conlan et al., 2010
	C3H/HeN	i.d., 105	No	Yes (i.d.)	42	Aero., 20	0 (5)	0 (11)	0 (5)	Conlan et al., 2010
	C3H/HeN	p.o., 108	No	Yes (p.o.)	42	Aero., 20	0 (5)	0 (5)	0 (5)	Conlan et al., 2010
ΔFTT0369c	BALB/c	i.d., 50	No	No	45	i.n., 10	90	ND	0 (5)	Rockx-Brouwer et al., 2012
		i.n., 10	No	No	45	i.n., 10	80	ND	0 (5)	Rockx-Brouwer et al., 2012
ΔFTT1676	BALB/c	i.d., 50	No	No	45	i.n., 10	100	ND	0 (5)	Rockx-Brouwer et al., 2012
		i.n., 10	No	No	45	i.n., 10	~50	ND	0 (5)	Rockx-Brouwer et al., 2012
ΔFTT0369ΔFTT1676	BALB/c	i.d., 50	No	No	45	i.n., 10	60	ND	0 (5)	Rockx-Brouwer et al., 2012
		i.n., 10	No	No	45	i.n., 10	10	ND	0 (5)	Rockx-Brouwer et al., 2012

Host strain: Mice: BALB/c, C57BL/6, or C3H/HeN mice; Rabbits: New Zealand White rabbits.

Interval: time between the only or the last vaccination and challenge.

SCHU S4 challenge route: .

Survival: % survival after challenge of mice immunized with the vaccine candidate (vaccine), LVS control (LVS), or no vaccine or PBS control (Sham). MST, mean/median survival time;

Time to death does not include survivors; ND, not determined.

Heat shock mutants

A defined SCHU S4 clpB mutant (SCHU S4ΔclpB) has been studied extensively for its capacity to induce protective immunity in BALB/c, C3H/HeN, and C57BL/6 mice (Conlan et al., 2010; Shen et al., 2010; Twine et al., 2012; Golovliov et al., 2013). Conlan et al. immunized BALB/c mice or C3H/HeN mice with 1 × 105 CFU i.d. or 1 × 108 CFU orally (p.o.) with LVS or SCHU S4ΔclpB, boosted or did not boost p.o., and challenged the mice 6 weeks later by aerosol with 20 CFU of the parental SCHU S4 strain. Unvaccinated mice served as controls. BALB/c mice immunized i.d. or orally with SCHU S4ΔclpB had 60 and 40% survival, respectively, significantly greater than those of naïve mice (0% survival) and mice immunized with LVS (0% survival), whereas C3H/HeN mice immunized i.d. or orally with the same vaccine had 0% survival. Boosting i.d. immunized BALB/c and C3H/HeN mice p.o. at week 8 did not improve the survival of mice against SCHU S4 challenge; boosting orally immunized C3H/HeN, but not BALB/c mice, with SCHU S4ΔclpB did improve protection against SCHU S4 challenge (Conlan et al., 2010). Others also showed similar protective immunity of SCHU S4ΔclpB in BALB/C but not in C57BL/6 mice (Shen et al., 2010; Twine et al., 2012; Golovliov et al., 2013). Introducing a second deletional mutation—one in capB—to SCHU S4ΔclpB (SCHU S4ΔclpBΔcapB) appeared to reduce its capacity to induce protective immunity against respiratory challenge with parental SCHU S4 (Golovliov et al., 2013; Table 3, Heat shock protein mutants).

Putative capsular mutants

Defined subsp. tularensis SCHU S4 mutants with a single deletion in capB (ΔcapB::Cam) or double deletions in FTT0918 and capB (ΔFTT0918ΔcapB) have been developed by Michell and Conlan et al. and evaluated as vaccine candidates (Conlan et al., 2010; Michell et al., 2010). Michell et al. showed that the s.c. median lethal dose for SCHU S4 ΔcapB::Cam, a single capB deletion mutant with a chloramphenicol resistance cassette (Cam) inserted at the deleted capB locus, is >1.6 × 106 CFU in BALB/c mice. The level of protection afforded by s.c. immunization with 104 SCHU S4ΔcapB::Cam is comparable to that of s.c. immunization with 104 CFU LVS against systemic (s.c.) challenge with 103 SCHU S4 56 days later. The SCHU S4ΔcapB::Cam vaccine was not tested against respiratory challenge (Michell et al., 2010). Conlan et al. showed that SCHU S4 ΔFTT0918ΔcapB administered i.d. is as attenuated as LVS in BALB/c mice (LD50 ≥ 107 CFU) but more virulent than LVS in C3H/HeN mice (LD50 < 105 CFU vs. LD50 > 105 CFU for LVS). In a virulence study, BALB/c and C3H/HeN mice infected orally with 108 CFU SCHU S4 ΔFTT0918ΔcapB had 80% (12/15) and 60% (9/15) survival, respectively (Conlan et al., 2010). In a study summarized in Table 3, Capsular mutant, BALB/c or C3H/HeN mice were not immunized, or immunized i.d. with 103 CFU or orally with 108 CFU ΔFTT0918ΔcapB or LVS, homologously boosted or not boosted orally, and challenged by aerosol 6 weeks later with 20 CFU SCHU S4. BALB/c mice immunized i.d. or orally with ΔFTT0918ΔcapB had 40 and 0% survival, respectively, after SCHU S4 aerosol challenge whereas none of the C3H/HeN mice immunized i.d. or orally with ΔFTT0918ΔcapB survived the challenge; nor did the naïve mice or mice immunized i.d. or orally with LVS. Homologous boosting orally did not significantly improve the protection against aerosol challenge with SCHU S4 except that C3H/HeN mice immunized i.d. and boosted orally with ΔFTT0918ΔcapB had improved survival (50% vs. 0% without boosting) (Conlan et al., 2010). In an earlier study, Twine et al. showed that the SCHU S4 FTT0918 single deletional mutant (SCHU S4 ΔFTT0918) had an i.d. LD50 of ~105 CFU and was thus 10-fold more virulent than LVS in BALB/c mice. BALB/c mice immunized i.d. with 105 ΔFTT0918 and challenged i.n. 9 weeks later with 10 CFU FSC 033 had 33% survival, while LVS-immunized mice had 0% survival after aerosol FSC033 challenge (Table 3, Other mutants) (Twine et al., 2005). The results of these studies suggest that single deletional mutants in the background of SCHU S4, although more attenuated than the parental SCHU S4 strain, are generally still more virulent than LVS. Introducing a second major attenuating deletion attenuates the mutant further but diminishes its capacity to induce protective immunity such that it is comparable to or less protective than LVS vaccination against virulent subsp. tularensis challenge.

Lipoprotein mutants

Qin et al. initially reported a subsp. tularensis SCHU S4 mutant with a transposon insertion at the FTT1103 locus (encoding a hypothetical lipoprotein); subsequently, they generated a defined subsp. tularensis SCHU S4 FTT1103 deletion mutant (SCHU S4 ΔFTT1103) (Qin et al., 2009, 2011). SCHU S4 ΔFTT1103 is highly attenuated in mice with an LD50 > 1010 i.n., and > 106 i.p., s.c., or i.v. C57BL/6 mice immunized once i.n. with 3 × 107, 1 × 108, or 3 × 108 SCHU S4 ΔFTT1103 and challenged i.n. 32 days later with 37–68 CFU SCHU S4 had 100%, 100% and 50% survival post-challenge; BALB/c mice immunized i.n. with 1 × 108 SCHU S4 ΔFTT1103 and challenged i.n. 33 days later with 95 CFU of the parental SCHU S4 strain had 75% survival post-challenge; however, there was no LVS control included in this study (Table 3, Lipoprotein mutants) (Qin et al., 2009, 2011). Recently, Reed et al. evaluated the vaccine efficacy of SCHU S4 ΔFTT1103 along with several other SCHU S4 mutants in a rabbit model (Reed et al., 2014). New Zealand White (NZW) rabbits were vaccinated via scarification with PBS, LVS, SCHU S4 ΔfibB (FTT1103), SCHU S4 ΔguaBA, or SCHU S4 ΔaroD; 30 days later, the animals were challenged with 1,000–10,000 CFU (~40–400 LD50) of aerosolized SCHU S4 and monitored for signs of illness and survival. Animals vaccinated with SCHU S4 ΔguaBA or SCHU S4 ΔaroD had 27 and 36% survival, respectively (Table 3, Nutrient metabolic mutants); none of the mock-, LVS-, and ΔfibB-vaccinated animals survived the SCHU S4 challenge (Table 3, Lipoprotein mutants) (Reed et al., 2014).

Other subsp. tularensis mutants

Other subsp. tularensis mutants, including SCHU S4 mutants with a single deletion in FTT0918, iglC, FTT0369, or FTT1676, or double deletions in FTT0369 and FTT1676 have also been reported; some have shown protection against i.n. challenge with SCHU S4 (Table 3, Other mutants) (Twine et al., 2005; Conlan et al., 2010; Rockx-Brouwer et al., 2012).

Other live attenuated recombinant vaccine candidates

Other live attenuated recombinant vaccine candidates have been developed by using heterologous vectors—adenovirus, Tobacco Mosaic Virus, and Listeria monocytogenes (Lm), or a homologous LVS mutant (LVS ΔcapB or LVS ΔLPS) vector to express/overexpress F. tularensis antigens (Jia et al., 2009, 2013, 2016; Kaur et al., 2012; Banik et al., 2015). Among these vaccines, some of the Lm-, LVS ΔcapB-, and LVS ΔLPS-vectored vaccines were tested against respiratory challenge with subsp. tularensis SCHU S4 and these are summarized in Table 4. We constructed seven recombinant Lm (rLm) vaccines using Lm ΔactA (a live attenuated actA deficient mutant) as a vector to express F. tularensis proteins, including T6SS protein IglC, metabolic enzymes AcpA, KatG, and Pld, and other proteins including bacterioferritin (Bfr), DnaK, and GroEL, and tested their protective immunity against LVS i.n. challenge in BALB/c mice. Among the seven rLm vaccines constructed, two of them, rLm/iglC and rLm/katG, were further tested for their efficacy against aerosol challenge with subsp. tularensis SCHU S4 (Jia et al., 2009). BALB/c mice were sham-immunized, or primed-boosted i.d. with Lm ΔactA (vector control), rLm/iglC, rLm/katG (heterologous vaccines), or the LVS control, and challenged six weeks later with 1 × LD50 or 10 × LD50 aerosolized Schu S4. Mice primed-boosted with rLm/iglC had a greater survival rate (100 and 75% post-aerosol challenge with 1 × and 10 × LD50 SCHU S4, respectively) than sham-immunized mice or mice immunized with the vector control, and the survival rates were comparable to that of LVS-immunized mice (87.5%). Mice immunized with rLm/katG also showed greater survival than sham-immunized animals (Table 4, Heterologous standalone vaccines) (Jia et al., 2009). In subsequent studies, mice primed at Week 0 with LVS ΔcapB or rLVS ΔcapB/IglC (prime vaccines homologous to F. tularenis), boosted at Week 4 with heterologous vaccine rLm/iglC, and subsequently challenged at Week 10 with 10x LD50 aerosolized SCHU S4 had a significantly greater survival rate (75%) than sham-immunized mice (0%) (p < 0.0001), and the survival rate was greater than that of the LVS-immunized mice (62.5%) (Jia et al., 2013). Mice primed-boosted with rLVS ΔLPS/IglC—rLm/iglC (1 or 2 boosts) and subsequently challenged with 3 × or 10 × LD50 aerosolized SCHU S4 also had significantly greater survival rates than sham-immunized mice and mice immunized with the prime vaccine only (Table 4, Homologous prime and heterologous boost vaccines) (Jia et al., 2013).

Table 4

Live attenuated heterologous vaccine candidates: Protection against SCHU S4 respiratory challenge.

Prime vaccine	Host strain	Prime route, dose (CFU)	Boost (vaccine, route)a	LVS control (route)b	Interval (days)c	SCHU S4 challenge route, dose (LD50)	% Survival post-challenge (MST, days)d			References
							Vaccine	LVS	Sham
HETEROLOGOUS STANDALONE VACCINES
Lm ΔactA(LmV)	BALB/c	i.d., 106	Yes (LmV × 1, i.d.)	Yes (i.d.)	42	Aerosol, 1	38	88	50	Jia et al., 2009
		i.d., 106	Yes (LmV × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	38	88	0	Jia et al., 2009
rLm/iglC	BALB/c	i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 1	100	88	50	Jia et al., 2009
		i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	75	88	0 (6)	Jia et al., 2009
rLm/katG	BALB/c	i.d., 106	Yes (rLm/katG × 1, i.d.)	Yes (i.d.)	42	Aerosol, 1	88	88	50	Jia et al., 2009
		i.d., 106	Yes (rLm/katG × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	25	88	0 (6)	Jia et al., 2009
HOMOLOGOUS PRIME AND HETEROLOGOUS BOOST VACCINES
LVS ΔcapB	BALB/c	i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	75 (19)	63 (17)	0 (5)	Jia et al., 2013
rLVS ΔcapB/IglC	BALB/c	i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	75 (20)	63 (17)	0 (5)	Jia et al., 2013
rLVS ΔLPS/IglC	BALB/c	i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 3	63 (16)	100 (21)	0 (4)	Jia et al., 2013
rLVS ΔLPS/IglC	BALB/c	i.d., 106	Yes (rLm/iglC × 2, i.d.)	Yes (i.d.)	42	Aerosol, 3	100 (21)	100 (21)	0 (4)	Jia et al., 2013
rLVS ΔLPS/IglC	BALB/c	i.d., 106	Yes (rLm/iglC × 1, i.d.)	Yes (i.d.)	42	Aerosol, 10	38 (11)	100 (21)	0 (4)	Jia et al., 2013
rLVS ΔLPS/IglC	BALB/c	i.d., 106	Yes (rLm/iglC × 2, i.d.)	Yes (i.d.)	42	Aerosol, 10	63 (15)	100 (21)	0 (4)	Jia et al., 2013

Boost: Heterologous standalone vaccines: mice were primed at Week 0 and boosted once (× 1) at Week 4 with Lm vector (LmV) or LmV expressing F. tularensis IglC (rLm/iglC) or KatG (rLm/katG); Homologous prime and heterologous boost vaccines: mice were primed at Week 0 with LVS ΔcapB or LVS ΔcapB overexpressing IglC (rLVS ΔcapB/IglC) or LVS ΔLPS overexpressing IglC (rLVS ΔLPS/IglC), and boosted with rLm/iglC once (× 1) at Week 4 or twice (× 2) at Weeks 3 and 6.

LVS control: in heterologous standalone vaccine studies, LVS was given i.d. twice at Weeks 0 and 4; in homologous prime-heterologous boost studies, LVS was given once at Week 4.

Interval: Time between the only or the last immunization and the challenge.

Survival, % survival after challenge of mice immunized with the vaccine candidate (vaccine), LVS control (LVS), or no vaccine or PBS control (Sham). MST: Mean Survival Time.

Summary and discussion

The vaccines summarized here include deletional mutants of subsp. holarctica LVS or FSC200 (Table 1), F. novicida U112 (Table 2), and subsp. tularensis SCHU S4 (Table 3), and homologous LVS mutants overexpressing F. tularensis antigens and heterologous vectors expressing F. tularensis antigens (Table 4). The unlicensed LVS vaccine, the only vaccine available in the U.S.A., has shown substantial albeit incomplete efficacy in humans but retains residual toxicity. As noted, it would seem reasonable to expect that any vaccine warranting further consideration as a human vaccine satisfy the following two criteria: 1) the vaccine is safer than LVS; and 2) the vaccine provides protection equivalent to or greater than LVS against respiratory challenge with subsp. tularensis SCHU S4 in appropriate animal models. The data summarized here show that it is relatively easy to generate genetically defined mutants that are safer than LVS so as to meet the first criterion; however, it is difficult to control the balance between attenuation and protection so as to meet the second criterion simultaneously. Practically speaking, among the vaccine candidates summarized here, only a few meet both criteria. Often, the LVS-derived vaccine candidates need either prime-boost vaccination or intranasal administration in order to provide very high-level protective immunity.

With respect to the relative efficacies of vaccine candidates, in many cases, vaccines and challenge strains have been tested under different conditions, e.g., different preparations of vaccine and challenge strains; different routes of vaccine administration (mucosal vs. systemic); different immunization-challenge intervals (typically ranging from 3 to 6 weeks); different routes and doses of challenge strain (less virulent subsp. holarctica or F. novicida vs. highly virulent subsp. tularensis SCHU S4); and different animal models (mice, rats, rabbits, or non-human primates), making it difficult to compare their relative efficacies. Of course, head-to-head comparisons are the most reliable way to compare vaccine candidates, but except for comparisons with LVS—the only vaccine tested and shown protective in humans and effectively the current gold standard—this is rarely done. We summarize vaccines that were tested against respiratory challenge with SCHU S4 and compared with LVS for efficacy in Table 5 and discuss factors that affect vaccine efficacy below.

Table 5

Attenuation and protective efficacy against SCHU S4 respiratory challenge of F. tularensis vaccine candidates relative to LVS.

Vaccinea	LD50 in mice (route, strain)	Efficacy ≥ LVS in mice against respiratory challenge with SCHU S4 (host strain)b			Vaccination—challenge interval (days) and other comments	References
		i.d.	i.n.	p.o.
LVS	~103 (i.n. BALB/c)>107 (i.d. BALB/c)>108 (p.o., C3H/HeN)				Toxicity	Fortier et al., 1991; Jia et al., 2009; Conlan et al., 2010
MORE ATTENUATED THAN LVS
LVS ΔpurMCD	>106 (i.n. BALB/c)		Yes with boost (BALB/c)		21	Pechous et al., 2008
LVS sodBFt	>104 (i.n. C57BL/6) >104 (i.n. BALB/c)		Yes (C57BL/6)		21	Bakshi et al., 2006, 2008
FSC200 ΔclpB	>105 (i.n. BALB/c)	Yes (BALB/c)			42; Less attenuated than LVS in SCID mice	Golovliov et al., 2013
LVS ΔcapB	>107 (i.n. BALB/c) >108 (i.d. BALB/c)	No (BALB/c)	Yes (BALB/c)		42; Need i.n. vaccination	Jia et al., 2010, 2013, 2016
LVS ΔcapB/IglA		Yes (BALB/c)			42	Jia et al., 2013
LVS ΔcapB/IglC		Yes (BALB/c)			42	Jia et al., 2013
LVS ΔcapB/IglABC		Yes (BALB/c)	Yes (BALB/c)		42	Jia et al., 2016, 2018
LVS::wzy	>107 (i.n. BALB/c)		Yes (BALB/c)		28	Kim et al., 2012
LVS::wbtA	>107 (i.n. BALB/c)		No (BALB/c)		28	Sebastian et al., 2007; Kim et al., 2012
Fn ΔiglD	>9.7 × 108 (i.n. BALB/c)				30; No protection in BALB/c mice; relevant efficacy to LVS in mice and rats not known; efficacy in NHP equivalent to LVS	Chu et al., 2014
SCHU S4ΔpurMCD	>106 (i.d. BALB/c) >106 (i.n. BALB/c)		Yes with boost (BALB/c)		21; Single deletion	Pechous et al., 2008
SchuS4ΔgurBA	>108 (in. C57BL/6)				30; Efficacious in rabbits; single deletion	Reed et al., 2014; Santiago et al., 2015
SCHU S4ΔfipB	>1010 (i.n. C57BL/6)				30; Less efficacious than LVS in rabbits; single deletion	Qin et al., 2009 Reed et al., 2014
SCHU S4ΔiglC	>108 (i.d. BALB/c)				42 or 63; Not efficacious; single deletion	Twine et al., 2005; Conlan et al., 2010
LVS ΔcapB +rLm/iglC	>107 (i.d. BALB/c) for both vaccines	Yes (BALB/c)			42	Jia et al., 2009, 2013
LVS ΔcapB/IglC +rLm/iglC	>107 (i.d. BALB/c) for both vaccines	Yes (BALB/c)			42	Jia et al., 2009, 2013
VIRULENCE EQUIVALENT TO LVS
SCHU S4ΔclpB	>107 (i.d. BALB/c)	Yes (BALB/c)		Yes (BALB/c)	42; Single deletion	Conlan et al., 2010; Shen et al., 2010
SCHU S4ΔclpBΔcapB	>107 (i.d. BALB/c)	Yes (BALB/c)			42; Survival ≤ 20%	Golovliov et al., 2013
LESS ATTENUATED THAN LVS
SCHU S4ΔFTT0918	~105 (i.d. BALB/c)	Yes (BALB/c)			42; More virulent than LVS in mice	Twine et al., 2005
SCHU S4ΔFTT0918 ΔcapB	≥ 107 (i.d. BALB/c) ~103 (i.d. C3H/HeN)	Yes (BALB/c)		Yes (C3H/HeN)	42; Protection in C3H mice ≥ LVS with i.d. prime and oral boost; more virulent than LVS in C3H mice	Conlan et al., 2010
VIRULENCE NOT COMPARED WITH LVS
SchuS4ΔaroD	Not available				21; More protective than LVS in rabbits; single deletion	Reed et al., 2014

Vaccine: Only vaccines that were tested against subsp. tularensis (Type A) respiratory challenge and compared with LVS are listed.

Efficacy relative to LVS: Percentage survival was used to compare the protective efficacy against respiratory challenge with a subsp. tularensis Type A strain between animals immunized with the vaccine candidate and animals immunized with LVS. Statistical significance was not available from some of the reported studies.

Vaccine and challenge strain stock preparation

As summarized in Tables 1–4, some studies used LVS as a positive control to evaluate the efficacy of various vaccines against respiratory challenge with SCHU S4 strains. It is interesting that while the median/mean survival time for unvaccinated or sham-immunized mice fell between 4 and 6 days post-respiratory SCHU S4 challenge in most studies, the immunity induced by LVS varied significantly in these studies. Of note, some vaccine strains were produced on solid agar while others in broth medium. Eigelsbach et al. conducted a study on virulence and immunogenicity of live vaccine strains. The study showed that LVS harvested from modified casein partial hydrolysate medium (MCPH) appeared more virulent and immunogenic in mice than LVS harvested from glucose cysteine hemin agar (GCHA); however, LVS prepared from GCHA and MCPH induced comparable protection in guinea pigs (Eigelsbach and Downs, 1961). While it is impossible to compare vaccines among different studies, it would be helpful to include LVS prepared using a standardized method as a positive control in efficacy studies.

Mucosal vs. systemic route of vaccine administration

As noted above, several live attenuated vaccine candidates induce more potent protective immunity against respiratory challenge with subsp. tularensis SCHU S4 when administered by the mucosal respiratory route (e.g., i.n., aerosol, or intratrachea), or by the mucosal oral route than by a traditional systemic route (i.d., s.c., or i.p.) (Hornick and Eigelsbach, 1966; Conlan et al., 2005; Wu et al., 2005; Pechous et al., 2008; Jia et al., 2010, 2013), with a few exceptions (Rockx-Brouwer et al., 2012). In one study, an alternative mucosal (i.e., oral) route for delivery of F. novicida-derived vaccine candidates showed greater protective immunity than the i.n. route against respiratory challenge with the virulent SCHU S4 strain (Cong et al., 2009). The i.n. route raises some additional safety concerns; that said, the current live attenuated flu vaccine administered i.n. has an excellent safety record (Pavot et al., 2012).

Interval between vaccination and challenge

As summarized in Tables 1–4, intervals between the last or the only vaccination and challenge ranged between 3 and 6 weeks in different studies. Eigelsbach and Downs investigated the effect of the vaccination-challenge interval on the immunity of LVS in mice and guinea pigs (Eigelsbach and Downs, 1961). Albino mice (Webster) vaccinated with LVS s.c. 15–30 days prior to challenge with 103 CFU of SCHU S4 s.c. had a higher survival rate (68–88%) than mice vaccinated 60 days prior to challenge (49–56%). This difference was appreciably greater in guinea pigs. Guinea pigs (Harley) vaccinated 15 days prior to challenge had 45% survival vs. 5% survival for those vaccinated 30 days prior to challenge. LVS administered i.d. or i.n. to mice was cleared from all the infected organs by 3 weeks (Jia et al., 2010). Thus, it would be helpful to challenge animals at a longer interval, i.e., more than 3 weeks, to minimize the effect of non-specific immunity and to allow evaluation of various vaccines under more rigorous conditions.

Hypo- and hyper- attenuation of vaccines

Some mutants of subsp. holactica LVS (i.e., LVS ΔpurMCD, LVS sodBκ, LVS ΔcapB, LVS ΔcapB/iglA, LVS ΔcapB/iglABC, and LVS Δwzy) and subsp. tularensis SCHU S4 (SCHU S4ΔpurMCD, SCHU S4ΔclpB, SCHU S4ΔclpBΔcapB) show significant attenuation and promising protective immunity against respiratory challenge in a murine model (Table 5) (Bakshi et al., 2006, 2008; Pechous et al., 2008; Qin et al., 2009; Sebastian et al., 2009; Jia et al., 2010, 2013, 2016; Shen et al., 2010; Kim et al., 2012; Rockx-Brouwer et al., 2012; Twine et al., 2012; Golovliov et al., 2013; Marohn and Barry, 2013; Straskova et al., 2015); other mutants, however, are either hypo- or hyper- attenuated, rendering them either poorly immunogenic or too virulent to use. LVS-derived vaccine candidates have deletions of at least three major virulence genes including two that were lost in the generation of the parental LVS strain (Salomonsson et al., 2009). Most immunoprotective SCHU S4 mutants, however, are single deletional mutants, raising the concern that they are only one mutation away from reversion to virulence, as seen with viral pathogens (Jia et al., 1999; Zhou et al., 2016). Therefore, a second major attenuating deletion is generally thought necessary—this typically markedly reduces their capacity to induce protective immunity. For example, the SCHU S4 ΔclpB mutant is highly attenuated (LD50 > 107 i.d.) and protective against respiratory challenge with ≤ 100 CFU SCHU S4 (40–100% of immunized BALB/c mice survived challenge)—more protective than LVS. However, introduction of a second major attenuating deletion in various genes (pmrA, relA, capB, wbtC, ggt, or fupA) significantly reduces its capacity to induce protective immunity against SCHU S4 challenge (<20% of mice immunized with the double deletional mutants survived SCHU S4 challenge)(Table 3, Heat shock protein mutants) (Golovliov et al., 2013). Another example is a SCHU S4 mutant with a single deletion in FTT0369c or FTT1676; these show significant protection against respiratory challenge with SCHU S4; however, a double deletion in both FTT0369c and FTT1676 significantly reduces the vaccine's capacity to induce protective immunity (Table 3, Other mutants) (Rockx-Brouwer et al., 2012).

Vaccine genetic background

Vaccines have been generated in the background of subsp. holarctica, subsp. tularensis, F. novicida, and heterologous vectors. The subsp. holarctica LVS strain is the only vaccine tested and shown efficacious in humans against virulent SCHU S4 challenge; however, its residual toxicity in humans and unknown attenuation mechanism may have presented obstacles to its licensure. LVS-derived vaccines are safer than LVS and retain the large antigen pool that might be required for protection against heterologous challenge with the virulent subsp. tularensis strain. However, a booster or intranasal vaccination route are generally required for enhanced vaccine-induced protection (Table 1). F. novicida is less virulent than LVS in mice, guinea pigs, rabbits and Fisher rats, and rarely infects humans (so far only 12 cases have been documented) (Kingry and Petersen, 2014). However, in contrast to LVS, F. novicida differs from F. tularensis in the mechanism of pathogenicity; they differ in cell surface structure, means of cellular entry, types of cells infected in vivo, and ability to evade host immune responses (Kingry and Petersen, 2014). The F. novicida parental strain and its derivatives have not shown efficacy against respiratory challenge with SCHU S4 in mice and guinea pigs by i.d. or i.n. route; the protective immunity induced by the i.t. or oral route against i.t. challenge with SCHU S4 in Fisher rats was not compared with that of LVS (Table 2). The subsp. tularensis-derived vaccines are generally more efficacious than LVS against homologous challenge with SCHU S4. However, this may be true only for SCHU S4-derived vaccines with a single deletion. A second major attenuating deletion significantly reduces vaccine efficacy (Table 3). The vaccines constructed using a heterologous vector (i.e., Listeria monocytogenes) have a much more limited antigen pool, need multiple vaccinations, and are less efficacious than LVS (Table 4).

The impact of vaccine genetic background on vaccine efficacy is also evident in comparisons of vaccines derived from different subspecies but comprising the same deletional gene mutation. For example, some gene deletional mutants in the LVS background are both highly attenuated and able to induce protective immunity against SCHU S4 challenge, but this may not be true of the same deletion in the F. novicida or SCHU S4 background. An LVS mutant with a deletion in purMCD, LVS ΔpurMCD, is both highly attenuated and able to induce protection against virulent SCHU S4 i.n. challenge; protective immunity is similar to that induced by LVS i.n. vaccination. However, an attenuated SCHU S4 with the same deletion, SCHU S4 ΔpurMCD, provides limited protection against SCHU S4 challenge, less than that induced by LVS vaccination (Pechous et al., 2006, 2008). Attenuated F. novicida mutants with similar deletions, ΔpurCD and ΔpurM, are not able to induce protection against the homologous wild-type strain challenge (Tempel et al., 2006; Quarry et al., 2007). The same findings have been reported for guaA, guaB, and guaBA mutants (Santiago et al., 2009, 2015). In contrast, clpB deletional mutants in the subsp. tularensis (SCHU S4) background induced full protection against respiratory challenge with the parent SCHU S4; a mutant with the same deletion in LVS showed no protection (Golovliov et al., 2013). Hence, the vaccine's genetic background is an important determinant of the vaccine's attenuation and protective efficacy.

Animal model

Various animal models—mice, rats, rabbits, guinea pigs, and non-human primates—have been used to study tularemia vaccine efficacy as reviewed recently by Elkins et al. (2016); however, they differ in their sensitivity to the highly virulent SCHU S4 strain and in vaccine-induced protective immunity against SCHU S4 challenge. Mice, guinea pigs, rabbits, and primates are more sensitive to SCHU S4 than rats (White rats and Fisher rats). The LD50 for SCHU S4 by a systemic route (s.c. or i.d.) is 1 CFU in mice, 1 CFU in guinea pigs, 1 CFU in rabbits, and >108 CFU (s.c.) in White rats; the LD50 of SCHU S4 by the respiratory route is 1-3 CFU in mice (i.n.), 1 CFU in cynomolgus macaques (aerosol), and >5 × 102 CFU in Fisher rats (intratreacheal); in humans, as few as 10–50 CFU SCHU S4 can cause clinical tularemia (Eigelsbach et al., 1951; McCrumb, 1961; Saslaw et al., 1961a,b; Schricker et al., 1972; Kostiala et al., 1975; Jemski, 1981; Conlan et al., 2003; Barker and Klose, 2007; Lyons and Wu, 2007; Raymond and Conlan, 2009; Wu et al., 2009; Ray et al., 2010; Chu et al., 2014; Kingry and Petersen, 2014; Hutt et al., 2017; Nguyen et al., 2017). Mice, rats, guinea pigs, and primates also differ in the degree of vaccine-induced protective immunity against virulent SCHU S4 challenge. Mice, guinea pigs, and humans vaccinated with the Foshay-killed vaccine were not protected against aerosol challenge with SCHU S4, while White rats were protected (Lyons and Wu, 2007). Furthermore, different strains within species show substantial variability in their susceptibility to challenge and the degree of vaccine-induced protection. LVS-immunized BALB/c mice are more resistant than LVS-immunized C57BL/6 mice to low dose aerosol or high dose i.d. challenge with virulent subsp. tularensis FSC 033 strain (Chen et al., 2003); however, C57BL/6 mice clear subsp. tularensis SCHU S4 infection more rapidly (Fritz et al., 2014). White rats and Fisher rats are more resistant to SCHU S4 challenge than Sprague–Dawley rats (Lyons and Wu, 2007; Raymond and Conlan, 2009). African green monkeys and cynomolgus monkeys are more sensitive to SCHU S4 aerosol challenge than Rhesus monkeys, with an aerosol lethal dose of 40, 32, and 2.8 × 105 CFU, respectively (Glynn et al., 2015). In addition, recent studies show that vaccines inducing strong protective immunity in one animal model may not do so in another model. For example, guaBA, aroD, and fipB (FTT1103) mutants have been tested in both mice and rabbits (Qin et al., 2009; Santiago et al., 2009, 2015; Reed et al., 2014). While the SCHU S4 ΔguaB and ΔguaA mutants, administered via scarification, induce partial protective immunity against respiratory SCHU S4 challenge in the New Zealand rabbit model, they do not do so in C57BL mice (Reed et al., 2014; Santiago et al., 2015). In contrast, the SCHU S4 ΔfibB (FTT1103) mutant, while fully protective in C57BL mice and partially protective in BALB/c mice, showed no protection against SCHU S4 challenge in the rabbit model (Qin et al., 2009; Reed et al., 2014). Other reports have reported differences in protective immunity conferred by the same vaccine in the murine and Fisher rat models (Cong et al., 2009; Signarovitz et al., 2012; Chu et al., 2014). These findings highlight the impact of animal model on the outcomes of preclinical vaccine efficacy studies.

The low natural incidence of tularemia renders field trials of efficacy unfeasible, and ethical considerations make it unlikely that tularemia vaccines will ever again be tested for efficacy in human challenge studies. In such situations, the FDA has promulgated the Animal Rule, whereby a drug or vaccine may be licensed on the basis of efficacy in relevant animal models. That raises the question as to which animal models are most relevant. If a vaccine is ineffective in the highly sensitive mouse model, are efficacy studies in the relatively resistant Fisher rat model an acceptable substitute? Proponents of this rat model would argue that the susceptibility of the Fisher rat to various F. tularensis strains more closely approximates that of humans than the mouse. Be it as it may, from the standpoint of efficacy, a vaccine that is efficacious in the most sensitive animal models would seem to be a more reliable one for humans, who likely have varying susceptibility to infection depending upon numerous host variables, than a vaccine efficacious only in relatively resistant models.

Conclusion

Since 2001, several promising live attenuated vaccine candidates have been developed that meet what would seem to be minimal criteria for a new human vaccine—safety greater than LVS and protective efficacy equivalent to or greater than LVS against respiratory challenge with subsp. tularensis SCHU S4 in appropriate animal models (Table 5). Some of these vaccines additionally demonstrate efficacy comparable to or greater than that of LVS against SCHU S4 respiratory challenge in the demanding mouse model. Vaccines meeting this higher standard include LVS mutants (LVS ΔpurMCD, LVS sodB, LVS ΔcapB, and LVS::wzy), another F. tularensis type B mutant (FSC200ΔclpB), LVS ΔcapB overexpressing F. tularensis T6SS proteins (LVS ΔcapB/IglA, IglC or IglABC), a LVS ΔcapB-rLm/IglC heterologous prime-boost vaccine, and a single deletional SCHU S4 mutant (ΔpurMCD). Another single deletional SCHU S4 mutant, SCHU S4 ΔclpB, and a double deletional SCHU S4 mutant, SCHU S4ΔclpBΔcapB demonstrates efficacy greater than LVS but its attenuation is equivalent to LVS. That these SCHU S4 mutants contain only one major attenuating deletion raises a safety concern, namely reversion to virulence. A second major attenuating deletion would alleviate this concern, but retaining efficacy upon the introduction of a second major attenuating mutation has been a major challenge for single deletional SCHU S4 mutant vaccines. The efficacy of the new vaccines has typically been greatest when administered by the intranasal or another respiratory route, but administering vaccines by this route raises additional safety issues. Nevertheless, vaccines that are safer than LVS and at least as efficacious, including by the i.d. route, have been developed, and they are promising candidates for going forward into more advanced animal studies such as in the non-human primate model and human safety trials.

Author contributions

QJ and MAH wrote the article. The comments in this article represent the opinions of both QJ and MAH.

Conflict of interest statement

The authors declare inventors on patents describing tularemia vaccines that are owned by UCLA.