Immune-related adverse events during anticancer immunotherapy: Pathogenesis and management.

Immunotherapy is one of the most recent systemic treatments to emerge for use in oncology, and is based on the blocking of inhibitory immune checkpoints to potentiate the immune response to cancer. The anti-cytotoxic T lymphocyte-associated antigen-4 antibody ipilimumab and anti-programmed cell death protein 1 antibodies, including nivolumab and pembrolizumab, are currently available and widely used, and other immune-inhibiting antibodies are now under intensive investigation. These antibodies have shown efficacy in a growing number of tumor types, following initial observations of their notable effects in melanoma treatment. Despite the efficacy of these antibodies, their novel mechanisms of action are also associated with a new class of side effects called immune-related adverse events (IRAEs). These side effects do not share a common pathophysiology with other anticancer treatments and, therefore, they often require specific therapies. When detected early and correctly treated, IRAEs are reversible; however, they can become severe and life-threatening if underestimated or inappropriately treated. This review aims to revisit the pathogenesis of IRAEs, with attention to gastrointestinal manifestations, since these are common and potentially dangerous complications of immunotherapy and represent a major cause of treatment discontinuation. Recommendations and guidelines for the management of IRAEs are also presented, in order to provide a clear and applicable algorithm for use by clinicians.

Introduction

Immunotherapy has become a new paradigm in cancer treatment since the reinforcement of immune surveillance has been shown to represent an efficacious approach to cancer immunotherapy (1). In this context, the interactions between tumor cells and stromal cells regulate the release of soluble factors that promote tumor progression, including vascular endothelial factor, interleukin-6 and transforming growth factor-β, which promote effector immune cells to strengthen their role in immune surveillance (2).

The inflammatory tumor microenvironment affects cross-talk between T cells and antigen-presenting cells (APCs), as well as between T cells and tumor cells, resulting in impaired cytotoxicity (3). Therefore, the antitumor response is regulated by the alternative expression of either activating or inhibiting immune checkpoint proteins by immune cells (4). In the context of cancer immunotherapy, two immune checkpoint receptors have been primarily studied, namely cytotoxic T lymphocyte-associated antigen 4 (CTLA4) and programmed cell death protein 1 (PD1), which are inhibitory receptors that control T cell activation in immune responses at various levels (5).

CTLA4 is exclusively expressed on T cells and primarily regulates the amplitude of the early stages of T cell activation, acting as a counterbalance to the activity of the co-stimulatory receptor cluster of differentiation (CD) 28 (5). Furthermore, the activation of T cells requires two sets of signals: The engagement of T cell receptors (TCRs), and a second signal that results from the binding of co-stimulatory receptors on the T cell with cell-surface molecules on APCs (5). CTLA4 is homologous to CD28 and the two receptors are localized on the surface of T cells where they compete to bind to the co-stimulatory ligands CD80 (also termed B7.1) and CD86 (also termed B7.2) on APCs (4–6). Furthermore, CTLA4 and CD28 are centrally important for the initial activation of naïve T cells induced by the migration of activated APCs to lymphoid organs (6).

In contrast to CTLA4, the principal inhibitory role mediated by PD1 is to limit the activity of T cells in peripheral tissues (including tumors) through the inhibition of TCR signaling and the downregulation of anti-apoptotic molecules and pro-inflammatory cytokines. PD1 expression on the surface of T cells occurs due to chronic and continuous antigen exposure and consequent lymphocyte activation, and defines an anergic or exhausted state. PD1 recognizes two known ligands, programmed death ligand (PD-L)1 (also known as B7-H1) and PD-L2 (also known as B7-DC), which are expressed on tumor cells, APCs and certain non-hematopoietic cells (4). Consequently, PD1/PD-L1 interaction induces apoptosis, inhibits T lymphocyte proliferation, survival and effector functions, and promotes the differentiation of T cells into Forkhead box P3-positive regulatory T cells (4,5).

Targeting these immune checkpoints can reinforce endogenous antitumor activity. The human CTLA4-blocking antibody, ipilimumab, demonstrated an overall survival (OS) benefit for patients with advanced melanoma (7). In addition, two PD1-blocking antibodies, pembrolizumab and nivolumab, have also exhibited favorable clinical activity in melanoma and other solid tumors, including non-small cell lung cancer, renal cell cancer, ovarian cancer and head and neck cancers (8,9).

Despite their clinical efficacy in terms of progression-free survival and OS, these immune checkpoint inhibitors induce novel toxicities in the form of tissue-specific inflammation or immune-related adverse events (IRAEs). Commonly affected tissues include the skin (rash, pruritus and vitiligo), bowel (diarrhea and colitis), liver (hepatitis and elevated liver enzymes) and endocrine glands (hypophysitis, hypothyroidism, thyroiditis and adrenal insufficiency) (10,11). These effects are mediated by T cell hyperactivation against self-antigens, similarly to autoimmune disorders, and have been more frequently reported with anti-CTLA4 blockade compared with PD1/PD-L1 inhibition (10). Even if responsive to corticosteroids and immunosuppressive agents, such as tumor necrosis factor-blocking antibodies for colitis or mycophenolate mofetil for hepatitis, IRAEs occasionally lead to discontinuation of treatment (11).

New evidence has shown improved clinical responses with the combination of anti-PD1 and anti-CTLA4 antibodies, at the cost of a higher incidence of drug-associated AEs of grade 3 or 4 compared with monotherapies (12). In a previous study, although the majority of IRAEs were treated and controlled, the discontinuation of the clinical trial due to IRAEs in the patient cohort under combination treatment was higher (55%) compared with the monotherapy with anti-PD1 or anti-CTLA4 antibodies (12,13).

Considering the promising results of immunotherapy, a coadjutant factor reducing the IRAEs could be advisable to avoid the use of corticosteroids or other immunosuppressive agents. This review revisits the recent advances in the knowledge of IRAEs, focusing on their pathogenesis, to propose novel strategies limiting these effects without interfering with the clinical efficacy of immunotherapy.

Epidemiology of IRAEs

IRAEs occur in up to 90% of patients treated with anti-CTLA4 and in 70% of those receiving anti-PD1/PD-L1 antibodies (Table I) (14,15). Grade 1 and 2 events are most common in the skin and the bowel, whereas grade 3 and 4 toxicities are prevalent in the digestive tract (16,17). The majority of IRAEs occur within 3–6 months of therapy (16,17) and the risk of developing IRAEs appears to be dose-dependent for anti-CTLA4 antibodies (18), but not for anti-PD1 agents. The combination therapy of ipilimumab with nivolumab provides significant clinical results, but also severe toxicities (9). The rate of grade 3 and 4 toxicities for such a combination is 55%, in contrast to monotherapies with nivolumab or ipilimumab, which have frequencies of 16 and 27%, respectively (9). Several studies have also described the additional toxic effects of combinatory immune checkpoint inhibition due to their different mechanisms of action (12,19,20).

Table I.

Incidence of IRAEs during anticancer immunotherapy with anti-CTLA4 or anti-PD1/PD-L1 antibodies.

	IRAE incidence (all grades), %
IRAEs	Anti-CTLA4 immunotherapy	Anti-PD1/PD-L1 immunotherapy
Dermatological (rash, pruritus, psoriasiform eruptions, vitiligo, Sweet's syndrome, Stevens-Johnson syndrome, toxic epidermal necrosis, pyoderma gangrenosum, cutaneous sarcoidosis)	44.0	37.4
Gastrointestinal (diarrhea, colitis, hepatitis, pancreatitis)	30.0	20.0
Fatigue	46.0	47.0
Endocrine (thyroid dysfunction, hypophysitis, adrenal insufficiency)	10.0	<10.0
Musculoskeletal	6.1	7.6
Mucosal toxicity (oral mucositis, dry mouth)	<5.0	5.0
Respiratory (pulmonitis)	1.0	<1.0
Ophthalmological (episcleritis, conjunctivitis, uveitis, orbital inflammation)	<1.0	–
Neurological (paresthesia, Guillain-Barré syndrome, aseptic or lymphocytic meningitis, posterior reversible encephalopathy syndrome, inflammatory enteric neuropathy, transverse myelitis)	<1.0	–
Renal (renal failure)	<1.0	1.0–22.0
Hematological (red cell aplasia, autoimmune neutropenia or pancytopenia, acquired hemophilia)	<1.0	–

IRAE, immune-related adverse event; CTLA4, cytotoxic T lymphocyte antigen 4; PD1, programmed cell death protein 1; PD-L1, programmed death ligand 1.

Skin toxicity is observed in almost half of patients treated with ipilimumab (44%); the majority of these cases are of grade 1 and 2 toxicity, whereas severe skin toxicity (grade 3–4) is recorded in <2% of patients. Skin toxicities observed with anti-PD1 antibodies include rash (14%), pruritus (10%), and occasionally psoriasiform eruptions (21). Vitiligo is the most frequent IRAE for anti-CTLA4 and anti-PD1 therapies in patients with melanoma (21). In addition, there have been several reported cases of Sweet's syndrome or Stevens-Johnson syndrome, as well as toxic epidermal necrosis, pyoderma gangrenosum and cutaneous sarcoidosis during anti-CTLA4 therapy, as well as exacerbation of pre-existing conditions, such as eczema, vitiligo or rosacea and extensive alopecia (22). In ~20% of patients treated with ipilimumab, a rash has been reported in the form of maculo-papular erythema on the trunk, back or extremities, mostly at grade 1 (22). Dry mouth affects ~5% of patients receiving immunotherapy (16), and oral candidiasis or Sjögren syndrome may also occur, although these are more frequently reported with PD1-inhibitors (14).

The most common gastrointestinal AEs include diarrhea, vomiting and colitis with abdominal pain or causing intestinal perforation (23). Gastrointestinal IRAEs generally occur after 6–7 weeks of treatment and include mesenteric vessel engorgement, bowel wall thickening and fluid-filled colonic distention; colitis may show a diffuse thickening of the colon wall on positron emission tomography-computed tomography (23). Colitis appears with mucosal erythema and ulcerations simulating Crohn's disease (23). In a meta-analysis including 10 studies and >2,000 patients treated with immune checkpoint inhibitors, diarrhea was frequently reported (11–51% of cases), whereas vomiting was only described in seven studies (3–32% of cases) and colitis in six studies (1–16% of cases) (19). The KEYNOTE-006 randomized open-label study has provided additional insight into the risks of different gastrointestinal toxicities from pembrolizumab (anti-PD1) vs. ipilimumab (anti-CTLA4). The findings revealed that diarrhea is more common during anti-CTLA4 (30% any grade and ~10% grade 3–4) than during anti-PD1/PD-L1 therapy. Furthermore, in this trial, the risk of colitis was 8.2% for ipilimumab vs. 3.6% for pembrolizumab (21).

Other research has suggested an increased risk of diarrhea and colitis with ipilimumab in comparison to nivolumab treatment. In a recently reported phase 3 trial evaluating combined nivolumab/ipilimumab therapy and monotherapy with ipilimumab or nivolumab, the risk of diarrhea and colitis was observed to be markedly higher in the ipilimumab-containing arms compared with the nivolumab monotherapy arm (12).

In patients treated with ipilimumab for melanoma, liver toxicity has been reported in ~5% of patients, particularly after 6 weeks of treatment, as elevated levels of hepatic enzymes and bilirubin, or as acute hepatitis (24). Immune-associated elevation of pancreatic enzyme levels has also been reported in immunotherapy-based protocols (25). Checkpoint inhibitor therapy can also induce a spectrum of rare cardiac side effects, including fibrosis, autoimmune myocarditis, cardiomyopathy, heart failure and cardiac arrest (26).

Approximately 5–10% of patients receiving immune checkpoint inhibitors develop an endocrine IRAE of any grade, including thyroid dysfunction (most often hypothyroidism) (21), hypophysitis (mainly observed with ipilimumab; 10%) (27), and adrenal insufficiency (with an incidence of ~6% for all grades and 1% for grades 3–4 with nivolumab and pembrolizumab treatment) (28). Fatigue is one of the most common side effects of immune checkpoint blockade, with a frequency of 47% in patients treated with anti-PD1 agents (16). Immune-associated pneumonitis occurs in ~1% of patients (29); severe forms are extremely rare with ipilimumab, whereas they have been frequently reported with anti-PD1 agents (30).

Ophthalmological and neurological IRAEs occur in patients treated with ipilimumab (31). Ocular toxicity (incidence, <1%) includes episcleritis, conjunctivitis, uveitis and orbital inflammation (31). Autoimmune neuropathies are rare (incidence, <1%) and include mild paresthesia as well as severe neurological syndromes such as Guillain-Barré syndrome, aseptic or lymphocytic meningitis, posterior reversible encephalopathy syndrome, inflammatory enteric neuropathy or transverse myelitis (32).

Arthralgia and arthritis are the most common rheumatic and musculoskeletal IRAEs, with an incidence of ~5% (33). There have been few reports of sicca syndrome, myositis or severe salivary hypofunction (33). A small number of cases of systemic lupus erythematous or polymyalgia rheumatic and giant cell arteritis have been described with CTLA4 blockade (34). Furthermore, the incidence of arthralgia was higher with combined ipilimumab/nivolumab immunotherapy (10.5%) compared with ipilimumab or nivolumab monotherapy (6.1 and 7.7%, respectively) in a previous study (33).

Kidney damage, including renal failure in patients treated with anti-CTLA4, has also been reported, with an incidence of 1% (35); this includes interstitial nephritis, granulomatous nephritis and glomerular lupus-like nephropathy (34). Renal dysfunctions or increases in serum creatinine are more common with nivolumab therapy compared with ipilimumab treatment (incidence, 1–22%) (36).

Hematological toxicity, including red cell aplasia, autoimmune neutropenia or pancytopenia and acquired hemophilia A, has also been reported in small number of patients receiving anti-CTLA4 antibodies (37).

Pathogenesis of IRAEs

The major immune checkpoint receptors, which include CTLA4 and PD1, perform a pivotal role in regulating the mechanisms of tolerance to self-antigens through the downregulation as well as the prevention of abnormal activity against self-antigens (38) (Fig. 1).

Figure 1.

CTLA4 and PD1 regulate different stages of T cell response. (A) T cell activation requires two complementary signals: The interaction between the TCR and peptide-MHC complex must be associated with a second co-stimulatory signal mediated by CD28. Conversely, the binding of CTLA4 to CD80/86 provides a control signal that suppresses ongoing T cell activation. (B) PD1 is upregulated on T cells following persistent antigen exposure. When PD1 binds to its ligand, PD-L1 or PD-L2, expressed by tumor cells, the T cell receives an inhibitory signal. Antibodies against CTLA4 or PD1/PD-L1 can activate T cells. CTLA4, cytotoxic T lymphocyte antigen 4; PD1, programmed cell death protein 1; TCR, T cell receptor; MHC, major histocompatibility complex; CD, cluster of differentiation; PD-L1, programmed death ligand 1; PD-L2, programmed death ligand 2; DC, dendritic cell.

The functions of the CTLA4 and PD1 pathways include the downregulation of T cell activation, which serves a significant function in the interactions between the immune system and cancer, as this may be attenuated by the influence of tumor cells. Furthermore, the continuous release of antigens by tumor cells within the tumor microenvironment has been shown to upregulate the inhibitory immune pathways as a result of chronic stimulation (4). Infiltrating T cells are frequently reduced due to the presence of CTLA4 and PD1 within the microenvironment, leading to impaired antitumor immunity (6). Once CTLA4 and PD1 bind to their ligands (CD80/86 and PD-L1/PD-L2, respectively), they negatively regulate intercellular interactions, even in the presence of tumor antigens (4). By blocking these interactions with CTLA4 and PD1, checkpoint inhibitors lead to increased T cell proliferation and activity, followed by an antitumor response and potentially by autoimmune reactions (39). Notably, certain polymorphisms of these immune receptor genes have been associated with increased susceptibility to various autoimmune diseases (39,40). However, the specific pathogenic mechanisms of IRAEs, which may occasionally be severe and life-threatening, remain largely unknown.

IRAEs have been associated with massive infiltration of highly-activated CD4+ and CD8+ T cells and an increased serum release of inflammatory cytokines (41). The most extensive data on the pathogenic mechanisms of IRAEs derive from studies on immunotherapy with CTLA4 inhibitors, in particular regarding the pathogenesis of anti-CTL4-associated gastrointestinal and dermatological effects. Berman et al (42) demonstrated that anti-CTLA4 agents induced the dysregulation of gastrointestinal mucosal immunity, as highlighted by the perturbation of enteric flora homeostasis. Variations of perinuclear anti-neutrophil cytoplasmic antibody staining and OmpC (E. coli) levels, as well as increased levels of neutrophil-derived fecal calprotectin, have been described (42). Despite this, calprotectin was not considered a predictive biomarker of IRAEs, but it only occurs in inflammatory bowel disease, indicating a different pathogenesis (42).

Since CTLA4 is highly expressed on the surface of regulatory T cells (Tregs), which have been indicated to downregulate cell-mediated immunity, an alternative hypothesis proposed that anti-CTLA4 antibodies cause an imbalance between Treg activity and effector T cell function. Indeed, anti-CTLA4 agents can induce significant peripheral blood Treg depletion, despite a high frequency of T-helper (Th)1 and Th17 cell subsets and increased levels of cytotoxic granzyme CD8+ T cells (43). Conversely, no differences in mucosal FoxP3+ Tregs in the colonic mucosa were observed between anti-CTLA4-treated patients with and without gastrointestinal IRAEs (44). Furthermore, an expansion of Th17 cells and elevated levels of serum IL-17 were associated with gastrointestinal disorders during immunotherapy (45).

Based on these data, a trial of neoadjuvant therapy with ipilimumab at 10 mg/kg demonstrated that baseline pretreatment with IL-17 is significantly associated with the risk of subsequent development of severe immune-mediated diarrhea (10). Host factors, such as genetic predisposition, associated with IRAEs have not been completely elucidated, although it is plausible that the incidence of gastrointestinal IRAEs may be associated with CTLA4 polymorphism alleles (42).

Dermatological IRAEs, including vitiligo, depend on T cell activation against melanocytes, which shows a perivascular infiltrate of lymphocytes and eosinophils into the epidermis (10), as well as of Melan-A-specific CD8+ T cells into the dermis (46,47). Notably, the prophylactic use of immunosuppressive therapy, such as corticosteroids, has not been shown to prevent the incidence of IRAEs (48).

Management of IRAEs

Gastrointestinal effects

Diarrhea and colitis are common IRAEs associated with anti-CTLA4 or anti-PD-1/PD-L1 use. Management of grade 1 diarrhea (defined as <4 stool evacuations above baseline per day) is based on fluid hydration, electrolyte repletion and anti-motility agents such as loperamide (Table II) (49). The cornerstone of diagnosis in patients suspected of severe acute infectious diarrhea (such as Clostridium difficile) is the microbiological analysis of stools, in association with a complete blood count and the measurement of serum inflammatory parameters (50). If symptoms persist, 9 mg of budesonide can be administered daily. The prophylactic use of budesonide has been tested during treatment with ipilimumab, without resulting in any difference in the incidence of diarrhea (51). Grade 2 colitis (4–6 episodes of diarrhea per day) can represent a risk factor for the development of a bowel perforation. Persistent symptoms in the absence of perforation require systemic corticosteroid treatment (methylprednisolone 0.5–1 mg/kg/day or oral equivalent). For severe (grade 3 or 4) toxicity, defined as ≥7 stools above baseline per day, peritoneal signs, bowel perforation or fever, immunotherapy should be permanently discontinued. Patients should be hospitalized for clinical monitoring and begin an appropriate intravenous (i.v.) electrolyte repletion. Following endoscopic evaluation, systemic corticosteroid treatment (methylprednisolone 1–2 mg/kg i.v. daily or equivalent) should be administered (50). High-dose methylprednisolone is indicated in clinically unstable patients (17). For severe or steroid-refractory symptoms, infliximab administration at a dose of 5 mg/kg every 2 weeks should be considered. Infliximab is contraindicated in patients with sepsis or intestinal perforation. In steroid- and infliximab-refractory patients, the use of tacrolimus or mycophenolate mofetil may be evaluated (52). However, the development of gastrointestinal toxicities during the administration of one immune checkpoint inhibitor does not preclude the use of another one (17).

Table II.

Schematic treatment algorithm for management of gastrointestinal adverse events during anticancer immunotherapy.

A, Diarrhea and colitis.
Severity of symptoms	Description	Management and follow-up
Grade 1	Diarrhea: <4 stools/day over baseline.	Continue ICPI
	Colitis: Asymptomatic	Supportive care: Oral fluid and anti-motility agents such as loperamide
		If symptoms persist: Budesonide 9 mg/daily
Grade 2	Diarrhea: 4–6 stools/day over baseline.	Delay ICPI and treat as grade 1
	Colitis: Abdominal pain; blood in stool.	If symptoms persist >5-7 days: 0.5–1.0 mg/kg/day methylprednisolone or PO equivalent
		If no improvement occurs manage as for grade 3–4
Grade 3	Diarrhea: ≥7 stools/day over baseline; incontinence. Colitis: Severe abdominal pain, medical intervention indicated, peritoneal signs.	Permanently discontinue ICPI 1.0–2.0 mg/kg/day methylprednisolone i.v. or equivalent Consider lower gastrointestinal endoscopy If symptoms persist: Infliximab 5 mg/kg every 2 weeks (if no contraindications)
		If symptoms persist: Consider alternative immunosuppressive therapy (such as mycophenolate mofetil and tacrolimus)
Grade 4	Life-threatening, perforation	As for grade 3
B, Hepatotoxicity.
Severity of symptoms	Description	Management and follow-up
Grade 1	AST or ALT >1 to 3× ULN; and/or total bilirubin 1.0–1.5× ULN	Continue ICPI Exclude liver injury induced by malignancies, alcohol, viral hepatitis or drugs
Grade 2	AST or ALT >3.0 to 5.0× ULN; and/or total bilirubin >1.5 to 3.0× ULN	Delay ICPI If symptoms persist >5-7 days or worsens: 0.5–1 mg/kg/day methylprednisolone i.v. or PO equivalent
Grade 3–4	AST or ALT >5.0× ULN; and/or total bilirubin >3.0× ULN	Delay or discontinue ICPI 1–2 mg/kg/day methylprednisolone i.v. or equivalent If symptoms persist: Consider alternative immunosuppression (e.g., mycophenolate mofetil)

ICPI, immune checkpoint inhibitors; ULN, upper limit of normal; i.v., intravenous; AST, aspartate aminotransferase; ALT, alanine aminotransferase.

Hepatotoxicity

Autoimmune hepatotoxicity manifests as an asymptomatic increase in serum transaminases and total bilirubin. Other causes of liver injury, including alcohol abuse, viral hepatitis or hepatotoxic medications, should be excluded. Ordinarily, the average time to resolution is 8 weeks. For grade 2 toxicity, immunotherapy should be withheld and, in case of persistence, corticosteroids (methylprednisolone 0.5–1 mg/kg i.v. or oral equivalent daily) are recommended. For grade 3–4 toxicity, immunotherapy should be permanently discontinued (50). Patients should be hospitalized and receive methylprednisolone (1–2 mg/kg i.v.). If symptoms persist, administration of mycophenolate mofetil (50) can be considered, and infliximab is not recommended (53) (Table II).

Dermatological disorders

Dermatological toxicities, including rash, pruritus and vitiligo, often occur in patients treated with immune-checkpoint inhibitors (54,55). During immunotherapy administration, grade 1 rash and pruritus can be managed with topical corticosteroids and systemic antihistamines. Delaying of immunotherapy is mandatory in cases of grade 2 toxicity; methylprednisolone at a dose of 0.5–1 mg/kg daily or oral equivalent is required with persisting symptoms. Furthermore, grade 3 rash necessitates systemic corticosteroid therapy (methylprednisolone 1–2 mg/kg daily) and discontinuation of immune-checkpoint inhibitor administration (49). Infliximab or mycophenolate mofetil can be used to manage refractory symptoms (53) (Table III). No treatment for vitiligo has been validated thus far (50).

Table III.

Schematic treatment algorithm for management of dermatological adverse events during anticancer immunotherapy.

Severity of symptoms	Description	Management and follow-up
Grade 1	Maculopapular rash <10% BSA, with/without symptoms (pruritus, burning, tightness)	Continue ICPI Supportive care: Anti-histamines and topical steroid
Grade 2	Maculopapular rash 10–30% BSA, with/without symptoms (pruritus, burning, tightness); limiting instrumental ADL	Delay ICPI Topical steroids If symptoms persist >7 days: Systemic steroids (such as methylprednisolone 0.5–1 mg/kg/day or PO equivalent)
Grade 3–4	Maculopapular rash >30% BSA, with/without symptoms (pruritus, burning, tightness); limiting self-care ADL; local or extensive superinfection	Delay or discontinue ICPI Methylprednisolone 1–2 mg/kg/day or PO equivalent Consider skin biopsy If symptoms persist: Consider alternative immunosuppressive therapy (such as mycophenolate mofetil or infliximab)

ICPI, immune checkpoint inhibitors; BSA, body surface area; ADL, activities of daily living; PO, per os.

Pneumonitis

Pneumonitis occurs later than other IRAEs (56). Although rare, it may be fatal, and an effective workup is therefore required. In a patient with a chronic productive cough, shortness of breath and hypoxia, chest X-ray and CT scans are diagnostic. Suspicious signs on CT scan include evidence of consolidative or ‘ground glass’ opacities with peripheral distribution (57). In mild cases, systemic corticosteroid treatment with prednisone 1–2 mg/kg or methylprednisolone 1 mg/kg daily can be administered. In more severe toxicities, hospitalization, discontinuation of the immune-checkpoint inhibitor and high doses of corticosteroids (methylprednisolone 2–4 mg/kg daily) are indicated, once pulmonary infections have been excluded. If symptoms persist, mycophenolate mofetil, cyclophosphamide or infliximab may also be administered (53,58) (Table IV).

Table IV.

Schematic treatment algorithm for management of pneumonitis, endocrinopathy and renal injury occurring as adverse events during anticancer immunotherapy.

A, Pneumonitis.
Severity of symptoms	Description	Management and follow-up
Grade 1	Asymptomatic; radiographic changes only	Continue ICPI
		Clinical or diagnostic observation
Grade 2	Symptomatic (mild to moderate new symptoms)	Delay ICPI 1 mg/kg/day methylprednisolone or PO equivalent Consider bronchoscopy and lung biopsy
Grade 3–4	Severe symptoms; worsening hypoxia; life-threatening	Discontinue ICPI 2–4 mg/kg/day methylprednisolone or i.v. equivalent Consider bronchoscopy and lung biopsy If symptoms are not improving within 48 h or are worsening: Consider alternative immunosuppressive therapy (such as mycophenolate mofetil, cyclophosphamide or infliximab)
B, Endocrinopathy.
Severity of symptoms	Description	Management and follow-up
Grade 1	Asymptomatic	Continue ICPI
		Hormone replacement
Grade 2	Symptomatic endocrinopathy	Delay ICPI
		1–2 mg/kg/day methylprednisolone i.v. or PO equivalent
Grade 3–4	Symptomatic endocrinopathy requiring urgent medical intervention, interfering with ADL. Grade 4: Life-threatening consequences (such as adrenal crisis)	Delay or discontinue ICPI 2 mg/kg/day methylprednisolone i.v. or equivalent If suspicion of adrenal crisis: stress dose of steroids with mineralocorticoid activity
C, Renal injury.
Severity of symptoms	Description	Management and follow-up
Grade 1	Creatinine 1.5× ULN	Continue ICPI
		Creatinine monitoring
Grade 2–3	Creatinine >1.5 to 6× ULN	Delay ICPI
		0.5–1 mg/kg/day methylprednisolone i.v. or equivalent
Grade 4	Creatinine >6× ULN	Discontinue ICPI
		1–2 mg/kg/day methylprednisolone i.v. or equivalent

ICPI, immune checkpoint inhibitors; ADL, activities of daily living; ULN, upper limit of normal; PO, per os; i.v., intravenous.

Endocrinopathy

Hypothyroidism and hypophysitis are the most common endocrine IRAEs. Therefore, thyroid function must be regularly assessed, whereas the pituitary axis should be tested only in suspected cases (52). Hypophysitis presents with signs of hypopituitarism (fatigue, hypoglycemia, hypotension and hypogonadism) and magnetic resonance imaging shows enhancement and enlargement of the pituitary gland (59). This condition is usually irreversible and requires permanent hormone replacement. When symptoms occur, methylprednisolone (1–2 mg/kg/day i.v. or oral equivalent) should be administered. A stress dose of i.v. corticosteroids with mineralocorticoid activity is indicated in cases of adrenal insufficiency. Immune checkpoint therapy must be delayed in symptomatic endocrinopathy and permanently discontinued in cases of severe toxicity (60,61). Symptomatic hyperthyroidism is managed with β-blockers and steroids (62). Once hypothyroidism is documented, hormone replacement represents the treatment of choice, with no indications for the deferral of immunotherapy (Table IV) (11).

Renal injury

Kidney failure presents with interstitial, granulomatous nephritis or glomerular lupus-like nephropathy. Grade 1 toxicity requires constant monitoring of serum creatinine once a week without discontinuing the ongoing immunotherapy. Interruption of the treatment is recommended in cases of toxicity of grade 2–3 unresponsive to steroids (methylprednisolone 0.5 mg/kg daily i.v.). In grade 4 toxicity, permanent discontinuation of therapy is mandatory, while renal biopsy and high-dose steroids (methylprednisolone 1–2 mg/kg daily i.v.) may be useful in cases of kidney impairment (Table IV) (50).

Immunosuppressant effect on anticancer immunotherapy

There is limited knowledge available regarding the impact of corticosteroids on the outcome of cancer treatment. For this purpose, a phase II trial was performed with ipilimumab monotherapy in advanced melanoma. In this study, 83 patients were monitored to determine the disease control efficacy in the presence (52% of patients) or absence (48% of patients) of steroid treatment for IRAEs (63). Systemic corticosteroid treatment of IRAEs did not appear to impact the development or maintenance of ipilimumab clinical activity in advanced melanoma. By contrast, data are still missing regarding the effects of immunosuppressive agents for IRAEs on the outcome of anti-PD1 therapy (64). Therefore, additional studies are required to understand whether the management of IRAEs with immunosuppressive agents has a detrimental effect on antitumor immunity.

Conclusions and future perspectives

Despite the promising results of trials with immunotherapeutic agents, this type of treatment can produces adverse effects through non-specific immunological activation, which may lead to the discontinuation of treatment. Therefore, targeting molecular mechanisms underlying the IRAEs is desirable to allow the continuation and completion of treatment. As steroids and immunosuppressive agents reduce T cell hyperactivation, other molecules could be used to limit the effect of IL-17. Indeed, the increase of this cytokine is significantly associated with the risk of developing severe immune-mediated AEs. Notably, the role of IL-17, as a pro-inflammatory cytokine, has been highlighted in experimental and human autoimmune disorders, including psoriasis, inflammatory bowel disease and multiple sclerosis (65).

A previous study indicated that the active form of vitamin D is able to exert a preventative effect in experimental models of autoimmune disorders, due partially to its direct suppressive effect on Th17 cells (65). Therefore, since Th17 cells are inhibited by vitamin D in autoimmune disorders, future therapeutic use of vitamin D during treatments with immune checkpoint inhibitors may be helpful in the prevention of IRAEs. Indeed, vitamin D could reinforce the efficacy of combination therapy with anti-CTLA4 and anti-PD1 through the well-known cytotoxic activity (66) and reduction of the incidence of IRAEs, thus avoiding the discontinuation of treatments.

Finally, evidence has demonstrated that the microbiota can regulate the clinical response to cancer therapy and the onset of toxic AEs (67). A previous study has described the association between variations in gut microbiota and the efficacy of immunotherapy with anti-CTLA4 and anti-PD1/PD-L1 checkpoint inhibitors, whose responsiveness is variable among patients (68). In vivo models demonstrated that CTLA4 antagonists induce T cell-mediated mucosal damage in the duodenum and colon in parallel to the dysregulation of intestinal and fecal microbiota. The inflammatory intestinal microenvironment induces the expansion of Th-17 cells and increases the risk of IRAEs such as colitis. The majority of findings supported that anti-CTLA4 blockade may alter the gut microbiota, thereby enhancing the antitumor activity.

Unlike CTLA4, PD1/PD-L1 blockade does not induce intestinal damage and this may explain the lower incidence of gastro-intestinal IRAEs during this treatment (69). Thus, targeting the microbiota could represent the newest resource to enhance anticancer efficacy and prevent toxicity resulting from immunotherapy.