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Alcoholic Hepatitis: Lost in Translation

  • Benjamin L. Woolbright*, and
  • Hartmut Jaeschke
 Author information
Journal of Clinical and Translational Hepatology 2018;6(1):89-96

DOI: 10.14218/JCTH.2017.00054

Abstract

Alcoholic hepatitis is the most severe and acute form of alcoholic liver disease. The mortality rate associated with alcoholic hepatitis is high, largely due to the lack of suitable pharmacological interventions. While there has been substantial research in the area, generating pharmacological interventions has been plagued by the lack of a robust mouse model both for testing and for understanding the underlying pathology. A number of major notable advances have been made in this area recently, with the goal of generating a mouse model of alcoholic hepatitis. The purpose of this article is to review recent advances in modeling alcoholic liver disease both in vitro and in vivo in the mouse, and place them in the context of the greater spectrum of alcoholic liver disease, with a focus on how we can translate current advances into a high-fidelity model of alcoholic hepatitis. In addition, we will review the basic mechanisms of alcoholic hepatitis as it is currently understood, focusing on recent advancements in diagnosis, prognosis and current pathophysiology, especially as it relates to the profound immune dysfunction present during alcoholic hepatitis.

Keywords

Alcoholic hepatitis, Alcohol, Liver disease, Cirrhosis, Prognosis, Keratin-18

Introduction

Alcoholic hepatitis (AH) is a type of acute-on-chronic liver failure associated with alcoholism and which has a high mortality rate.1 Corticosteroid treatment is still the gold standard pharmaceutical intervention, but has minimal efficacy.2 Orthotopic liver transplantation is the most effective cure, but there is a moral conundrum associated with giving valuable livers to patients with ongoing alcoholism, especially given the high rates of recidivism in the population.3 Moreover, the number of livers available for transplantation is limited compared to the number of AH patients in most regions, and more information is necessary to fully understand what populations respond positively to transplantation.4–6 As such, pharmacotherapy is urgently needed for this patient population.

A number of clinical trials or pilot studies have tried agents that target inflammation or inflammatory cell death, based on studies performed in the mouse model.2,7–9 There have been a few cases of positive results, and none of these agents have been translated into a legitimate clinical therapeutic candidate. This is partially due to the incredible complexity of AH pathology; however, another increasingly well understood factor is the lack of suitable models for generating therapeutic candidates for late stage alcoholic liver disease (ALD).1,10–12 As such, a major imperative in the basic science of ALD remains the generation of a high-fidelity mouse model of AH, or advanced ALD. In this review, we will attempt to bridge the gap between the mouse model and clinical AH, by defining current obstacles and highlighting innovative recent solutions to this growing dilemma.

Acute alcoholic hepatitis – Much more than just steatosis and inflammation

Understanding AH as a clinical disorder is necessary to obtain mouse models that accurately model the disease. AH patients commonly present to the hospital with one or more co-morbidities, including jaundice, esophageal varices, or fever due to co-infection.13 Underlying cirrhosis can remain silent for years prior to these precipitating events, but is present in up to 80% of AH patients.14 An overwhelming majority present with some degree of fibrosis, indicating significant chronic liver disease.14 As such, the largely silent nature of ALD in human patients is a major hurdle for early diagnosis, and a major contributor to the associated morbidity and mortality.1,15

Histologically, patients with AH commonly present with marked fibrosis, steatosis and cholestasis or bilirubinostasis in the liver.14 Patients also commonly present with elevations in plasma bilirubin, plasma creatinine and the international normalized ratio (INR), consistent with major liver and kidney dysfunction. Combinations of INR ratio, plasma creatinine and plasma bilirubin levels, make up the bulk of a number of prognostic batteries that will be discussed later in this review.16–18 As such, the major dysfunction associated with AH could be classified as an abrupt lack of liver function, that is associated with major underlying liver disease, severe inflammation and a faulty homeostatic balance of functional hepatocytes.

Surprisingly, one factor that is rarely elevated is the common marker of hepatocyte injury, plasma alanine aminotransferase (ALT). Patients with AH typically have very minor elevations in ALT, commonly less than 1.5-fold higher than the upper limit of normal. While aspartate aminotransferase (AST) values can rise as high as 200–300 IU/L, values much above this are typically considered diagnostically unlikely to be AH, and mean values in large studies are typically closer to 90–150 IU/L.2,14 AST activities are commonly elevated and AST>ALT is a common diagnostic indicator of AH versus other types of liver injury.19

Given that AST is expressed in multiple organ systems other than liver, the AST>ALT ratio may be indicative of cell death in other organ systems. These relatively low values of AST/ALT suggest only minor levels of necrosis occur in AH patients, which is supported by data that a majority of cell death during AH appears to be through apoptosis.9,20 Even still, measurements of apoptosis return very low levels of overall cell death.21 TUNEL stains on AH biopsies indicate that AH patients undergo relatively minor levels of cell death, when compared to diseases with major acute parenchymal injury.9,21 While some degree of cell death certainly occurs during AH, these data call into question whether or not cell death plays a critical role in AH progression.21

Neither AST nor ALT plasma activities are strong predictors of outcome in AH patients.21 It should be noted, though, that ALT values may be partially suppressed due to an overall reduction of ALT activity in the liver of AH cirrhotics.22 The limited degree of cell death that occurs during AH is likely not a mitigating disease factor acutely; although, the chronic cell death that occurs during the course of ALD is still a potential driver of subsequent inflammation, fibrosis and eventual cirrhosis.

Liver regeneration, which typically occurs as a subsequent response to cell death, is also highly dysregulated in AH patients. Cirrhotic patients have regenerative nodules that are universally or widely positive for proliferating cell nuclear antigen, suggesting widespread attempts at hepatocyte proliferation.23 This is suppressed in AH patients though, as these patients depose laminin instead of fibronectin, which pushes progenitor cell expansion away from mature hepatocyte differentiation, towards the bile duct epithelial cell lineage.24 The enhanced proliferation of biliary epithelial cells also seen in AH patients is also observable in the number of liver progenitor cells proliferating, which both serve to reduce the number of mature hepatocytes available to perform normal liver functions.24,25 This lack of mature hepatocytes may be a major driving factor in the lack of liver function and the subsequent liver failure. Therapeutic interventions aimed at promoting the maturation of hepatocytes and the deposition of normal extracellular matrix are an interesting therapeutic avenue for increasing liver function in alcoholic cirrhotics and AH patients.

In addition to liver dysfunction, many patients also have dysfunction of other organ systems, such as kidney and gut, which is intrinsically linked to both multiorgan system dysfunction and survival.26–29 AH patients suffer from a dysfunctional immune response as well, including elevated plasma leukocyte counts which, paradoxically, does not result in an effective immune response, as these patients are at a dramatically increased risk of systemic inflammatory response syndrome.30 This may be due to a well-characterized immune cell dysfunction in AH patients including alterations in initiation of respiratory burst in neutrophils and monocytes, and a faulty myeloperoxidase enzyme in neutrophils from cirrhotics.31–33

The lack of a normal myeloperoxidase enzyme might explain why these patients also have a paradoxical lack of chlorotyrosine adducts associated with neutrophil-mediated liver injury, despite considerable neutrophil deposition and activation.34,35 The role of neutrophils in AH is still under debate, as some evidence points towards neutrophils being drivers of AH while other studies indicate the opposite.14,36–39 Given the extended time course of AH in patients, neutrophils may play a contextual role based on current patient status. Unfortunately, very limited information is available on the time course of neutrophil activity in ALD patients, as so few patients are identified during the early portion of the disease.12 A greater understanding of neutrophil and monocyte dysfunction during AH is necessary to better understand how and why these patients become susceptible to infection.

Diagnosis, prognosis and presumed mechanisms

AH occasionally represents a diagnostic dilemma for clinicians. The use of transjugular biopsy (TJB) is the recommended means of differentiating between diagnoses, as it can definitively provide an answer; although, a number of detractors accurately point out that biopsy comes with inherent risk in patients with bleeding susceptibility, and may only be of limited availability in rural settings.1,2,40 As such, The American Association for the Study of Liver Disease has not yet fully endorsed TJB.40 A number of plasma biomarkers have been investigated for when TJB is either unavailable or too risky, though.

Plasma values of keratin-18 are dramatically elevated in AH patients, and may serve as a means for diagnosing the AH population.41 While plasma keratin-18 values are typically measured in the context of cell death, AH patients have dramatic elevations without the typically associated increases in plasma transaminases, or lactate dehydrogenase (Fig. 1).21 Why this occurs remains a mystery, although it is currently under investigation.21 Transient elastography can also identify alcoholic cirrhosis (AC) with some specificity and sensitivity, although its use in AH is likely limited.42 Alcoholic steatohepatitis (ASH) test is a novel multiparameter test with good specificity, and specificity that may be useful in some patient populations or in centers with limited potential for biopsy.43 A highly sensitive and specific test for diagnosis of AH would be incredibly valuable, as it would preclude the need for TJB in highly at-risk patients, or in hospital settings where TJB is not immediately available.

Ratio of K18 (M65) to plasma alanine aminotransferase (ALT) activity compiled from multiple studies.
Fig. 1.  Ratio of K18 (M65) to plasma alanine aminotransferase (ALT) activity compiled from multiple studies.

K18:ALT was calculated in a series of studies on different clinically relevant liver diseases. Acetaminophen (APAP) data are derived from Antoine et al.99; obstructive cholestasis data are derived Woolbright et al.56; alcoholic cirrhosis (AC) and alcoholic hepatitis data are derived from Woolbright et al.21

Prognosis of AH has been more widely investigated, as a diagnosis of AH has a 28-day mortality rate of 25–40%.1 A number of metrics have been evaluated for their ability to predict mortality in the population. Perhaps the most common is Maddrey’s discriminatory function score based on prothrombin time and bilirubin levels.44 This is a modified metric, where scores above 32 indicate severe dysfunction and recommend the use of corticosteroids.44 The model for end-stage liver disease score was also adapted for use in AH and was reported to predict outcome more effectively than Maddrey’s, presumably due to taking into account kidney function, which is linked to survival.17,26 The Lille score is a dynamic scoring system and not only predicts outcome in patients but also serves to determine whether or not patients are responders or non-responders to corticosteroid treatment using multiple measurements over 7 days.18

Recently, combinations of these scores were shown to be even more effective.45 The ABIC scoring system is also widely reported in the literature and essentially is as effective as Lille or Maddrey’s.16 Recently, our own group and others have reported that plasma keratin-18 ratios may also be highly predictive of mortality, despite the fact that plasma keratin-18 levels in AH appear to be disproportional to traditional measures of liver cell death in plasma.21,46 The use of prognostic scores has been a major source of understanding of clinical AH. As direct intervention is cumbersome and risky in human patients, identifying markers associated with survival or non-survival is critical to understanding the disease.

A number of different factors associated with the immune response have been correlated with survival and non-survival. Interestingly, some of these values can be viewed as contradictory in nature (i.e. plasma IL-8 values are elevated in non-surviving AH patients), yet neutrophil infiltration seems to be important for survival.14,36,39 Hepatic expression of CXC chemokines, though, is also linked to poorer survival outcomes, suggesting hepatic inflammation is detrimental to outcome.37 The lack of clarity in these data have led to some dichotomy between the basic science fields and the clinical science fields with regards to the role of neutrophils in AH.

Neutrophil infiltration has long been a desired aspect of mouse models, due to their noted presence and presumed pathological significance in AH patients, and recent advancements were rightfully hailed for their incorporation of legitimate neutrophil infiltration into the model, achieved solely with the use of alcohol.47,48 The Gao-binge model is dependent on the presence of neutrophils for cytotoxicity, as prevention of neutrophil extravasation by depletion of E-selectin is strongly protective.48 Thus, a number of recent studies using this model have capitalized on this finding and demonstrated a reduction in neutrophil recruitment or activity, and suggested the immunomodulatory activity as a potential therapeutic for AH, despite the fact that histological evidence and clinical evidence indicates that global inflammatory suppression might be highly detrimental in some patients.7,39,49–51 As noted above, neutrophils very likely play multiple roles during the course of the disease and should be investigated contextually in the future.

Even so, other markers of survival act to reinforce each other. In the instance of cholestasis, a majority of research indicates that concurrent cholestasis in patients or murine models with alcoholic liver injury dramatically worsen outcomes. In murine models, ethanol feeding dramatically exacerbates cholestatic liver injury induced by bile duct ligation (Woolbright and Jaeschke, unpublished data). Plasma bile acid values are elevated in patients with AH.52 Total plasma bile acid levels, cholic acid levels and chenodeoxycholic acid levels also correlate with severity of liver disease in ALD patients.52 Concurrent cholestasis, plasma bilirubin levels, and low deoxycholate/glycodeoxycholate levels, indicative of intrahepatic or extrahepatic bile duct blockage, are all strongly associated with mortality; however, it is unknown whether this is a primary cause or a secondary effect of the lack of liver function.37,44,52,53 Bile acids are thought to be hepatotoxic in large concentrations, especially when hepatocytes are exposed to leakage from the biliary tracts.54–56 Bile acids themselves are also pro-inflammatory and may contribute to the inflammation seen in AH patients when there is advanced jaundice and cholestasis.56,57 More research is needed using patient samples to establish whether or not some of these effects are potentially causative or a byproduct of the loss of liver function.

Alcoholic liver disease in the mouse – Limited pathology

Mouse model – Mechanisms

A number of authoritative reviews have been written on mechanisms of alcoholic steatosis, alcoholic gut dysfunction, and the subsequent effects in mouse models of ALD.58–60 This review is an attempt to focus on translation of these findings into actionable targets, and thus these mechanisms will only be touched upon briefly.

Alcohol is widely considered to be unpalatable to most rodent species, and, thus, ad libitum administration to rodents rarely results in blood alcohol levels commensurate with human exposure or human disease.61 The limited increase in blood alcohol concentrations may also be due to faster metabolism of alcohol by rodents, and is likely a component of the reduced pathology observed in murine models. Regardless, alcohol is rapidly metabolized by the mammalian body through numerous pathways, but primarily through alcohol dehydrogenase and cytochrome 2E1, and in small quantities through glucuronidation.62–64 Ethanol is converted to acetaldehyde by alcohol dehydrogenase, and to acetic acid by aldehyde dehydrogenase.62 Some additional detoxification occurs through cytochrome P4502E1 (CYP2E1), through a similar pathway as alcohol dehydrogenase.63 Acetaldehyde is far more reactive than either ethanol or acetic acid and, thus, is a likely source of cellular stress in ALD patients.65

Long-term alcohol consumption alters NADH to NAD+ ratios through the alcohol dehydrogenase pathway, as this pathway uses NAD+ as a co-factor.66 This shift alters the activity of histone deacetylase sirtuin-1, which affects numerous signaling pathways related to lipid metabolism. This includes activation of sterol response element binding protein-1, which enhances lipogenesis, and a reduction in peroxisome proliferator activated receptor co-activator gamma signaling leading to reduced fatty acid oxidation and accumulation of short chain hydrocarbons.67,68 The effect of this simultaneous dysregulation of metabolism is considerable accumulation of triglycerides in hepatocytes, leading to the characteristic steatosis present in alcohol-treated animals or cells.66–68

Most current research is focused on these processes, and our understanding of this process is far greater than the subsequent events in the mouse. Unfortunately, while simple steatosis is present in a majority of AC and AH patients, the pathology associated with simple steatosis alone is minimal, and most patients present at a point considerably past steatosis (Fig. 2).69 Moreover, steatosis is rapidly resolved by abstinence, which remains a mainline therapy for ALD and AH, and, thus, the likelihood that addressing liver steatosis as an effective therapeutic target for AH is minimal, as it is self-resolving in compliant patients.70,71

Disease severity in patients versus alcohol model progression.
Fig. 2.  Disease severity in patients versus alcohol model progression.

A majority of models fail to recapitulate the disease severity observed in AH patients.. Abbreviations: ACLF, acute-on-chronic liver failure; AH, alcoholic hepatitis; HCC, hepatocellular carcinoma.

Considerable oxidative stress builds rapidly upon chronic alcohol exposure. This is likely from multiple sources, including Kupffer cell-mediated oxidative stress, mitochondrial dysfunction in hepatocytes and the production of reactive metabolites.72–74 It has been hypothesized that CYP2E1 can be a relevant source of reactive oxygen species (ROS) during alcohol exposure; however, others have questioned this hypothesis and suggested a role of NADPH oxidase in Kupffer cells as the main source of alcohol-induced oxidant stress.75 Regardless, a number of different products from ROS-mediated damage are measurable after alcohol exposure, including 4-hydroxynonenal and 3-nitrotyrosine.76 These species likely contribute to cell death after alcohol consumption, but also activate measures such as autophagy.77–78

As autophagy removes both damaged mitochondria and lipid droplets, this is likely a protective measure against ROS-damaged species in alcohol-fed mice.77 Selective mitophagy, or the removal of damaged mitochondria, through the protein parkin is protective against alcohol-induced liver injury, as knockout of parkin dramatically exacerbates injury in alcohol-fed mice.78 This is due to preservation of normal mitochondrial function and removal of mitochondria damaged by excessive ROS production and alcohol metabolism.79 It is currently unknown as to whether selective or non-selective autophagy also occurs in human patients; although, this might be another potential therapeutic avenue for reducing cell death and enhancing hepatocyte function.

Simultaneous to liver dysfunction, alcohol causes severe gut dysfunction.80 The “leaky gut hypothesis” was an initial explanation as to why lipopolysaccharide (LPS) levels were elevated in alcoholics and alcohol-exposed mice.81 Chronic alcohol exposure causes intestinal overgrowth of bacteria and tight junction dysfunction in the gut.82 The combination of these two factors allows for bacteria to spill out from the gut, which increases plasma LPS levels.80 In human cirrhotics, this effect can be ameliorated by gut sterilization with high doses of rifaximin, designed to prevent the generation of ammonia and reduce hepatic encephalopathy.60,83

Elevated LPS levels in the mouse model activate toll-like receptor-4 (TLR-4) on Kupffer cells.84 This results in production of tumor necrosis factor-α (TNF-α) and release of ROS mediated by NADPH, which induces cell death in hepatocytes and provokes inflammation.84,85 Ablation of TLR-4 expression is protective against injury in the mouse model.84 The role of TLR-4 has been confirmed repeatedly in subsequent studies by multiple groups.85 This initially led to TNF-α blockers being assessed in patients; however, the clinical results were disappointing, as the blockade of inflammation led to sepsis in the patient population and higher mortality.7 Surprisingly, in most models of pure alcohol administration, the TNF-α release does not result in overt neutrophil accumulation, fibrosis or cirrhosis.12 Administration of other agents is typically required, and represents a major hurdle for generating a high-fidelity mouse model.

The mouse model of ALD – What it is and what it is not

The rodent model of ALD has evolved since the original experiments from DeCarli and Lieber identifying a liquid diet that was capable of inducing steatosis in the mouse.86 While DeCarli and Lieber used rats, the existence of a remarkable number of tools in the mouse has led to its surge as the primary animal model of use in the laboratory. Four- to six-week feeding with the liquid diet induces steatosis and mild elevations in plasma transaminase activity consistent with very early stage ALD. Extended time frames, the addition of different pathogenic molecules (such as LPS to enhance inflammation or carbon tetrachloride (CCl4) to induce fibrosis), the use of binge dosing on top of subacute dosing, direct intragastic infusion, and hybrid alcohol/high-fat diets has led to a much more robust pathology.48,87–92

The above-listed mechanisms of alcohol metabolism, hepatic steatosis and alcohol-induced inflammation in the mouse were all largely discovered in one of these associated models, validating the usefulness of these models in understanding the effects of alcohol on mammalian physiology. Advantages and disadvantages of each model are summarized in Table 1. However, the plurality of the common findings associated with AH either have not been demonstrated or are more tightly associated with the adjuvant treatment, such as in the case of liver fibrosis in mice treated with alcohol and CCl4, in mouse models of ALD. This includes: major elevations in plasma bilirubin or INR, indicating loss of liver function, multiorgan dysfunction syndrome, concomitant cholestasis, bridging fibrosis, cirrhosis, regenerative nodules of hepatocytes, progression to hepatocellular carcinoma, and acute-on-chronic type liver failure. Unfortunately, increasingly well acknowledged flaws exist that require remediation if the mouse is going to serve as the major laboratory model for ALD. Translating the above findings will require innovation from the field as a whole, and advancement of the underlying pathology present in clinical patients.

Table 1.

Comparison of clinical parameters and histological findings in widely used mouse models of alcohol exposure and human AH patients

L-C dietGao-binge“Hybrid” gastric infusionHuman AH patients
AST, U/LSlight elevationElevated 100–300 U/LElevated 100–200 U/LElevated 80–120 U/L
ALT, U/LSlight elevationElevated 100–300 U/LElevated 100–200 U/LMild elevation
BilirubinNo increaseNo increaseNo increaseElevated 3–30+ mg/dL
INRNo increaseNo increaseNo increaseCommonly elevated
BilirubinostasisNoneNoneNoneCommon
PMN infiltrationNo increaseSignificantSignificantSignificant
FibrosisNoneNoneNoneUp to 98% of patients
CirrhosisNoneNoneNoneUp to 80% of patients
Liver failureNoneUnknownUnknownACLF

Lost in translation – How do we turn basic science findings into clinical results in the alcohol field?

With the limited pathology available in mice, how do you attempt to translate these findings into a more complete understanding of clinical manifestations of ALD? A number of groups have aggressively pursued better models, especially in recent years.48,88–92 While the obvious clinical need is an effective therapeutic, the most critical need for the basic science field is not therapeutic candidates but models of ALD that recapitulate all aspects of the human pathophysiology. Unfortunately, this task has proven difficult for the field, for a number of the reasons listed in this review. New models are being generated every year at this point as the field recognizes that current models are inefficient and unlikely to translate to the clinic. In the interim, additional methods are constantly being developed to help bridge the gap between mice and humans. A number of notable studies with innovative attempts at bridging this gap have recently been published or presented and will be discussed in the subsequent sections.

It is clear that patients with AH present with three critical factors that are either missing or are poorly established in mouse models: 1) the presence of major underlying liver dysfunction (i.e. fibrosis or cirrhosis) before the onset of liver failure (acute-on-chronic liver failure); 2) severe multiorgan dysfunction; and 3) dysfunctional innate immune responses. This is a critical point of understanding: mouse models fail to recapitulate any of these underlying factors, with the possible exception of point 3. Even the most advanced models typically only recapitulate findings up to the point of steatohepatitis (Fig. 2).48,91 This state can occur undetected for decades before the onset of full-blown cirrhosis or concurrent AH, and is not a single event precipitated by a single binge but more likely the result of cumulative binges in both mice and humans.91,92 Moreover, inflammation in the setting of steatosis is benign compared to the advanced pathology associated with cirrhosis or AH.

While human patients likely encounter a similar progression of pathology at some point, there is no diagnosis of ALD for the overwhelming number of patients during this period. AC and AH patients commonly present at or near the end of their disease.1 This is clearly evidenced by the high mortality rate associated with AH.1 Thus, interventions that attempt to target this period would require a dramatic paradigm shift in the diagnosis of ALD. As such, interventional studies should be re-evaluated in the context of more advanced ALD.

Experimental therapeutic intervention in murine models should be initiated after the major onset of pathology and not before pathology begins. These studies can coincide with prophylactic studies that address the role of the protein in progression of the injury. Knockout mouse models have become the gold standard for the assessment of protein function during disease. While the authors of this review concur with their use in assessment of protein function during disease, they do not always make excellent therapeutic models. This is especially true in the case of chronic disease states, where an intervention is only possible in the later stages of the disease.

A number of different mechanisms for selective protein knockdown have become more widely available in recent years, including knockdown via the hepatotropic adeno-associated virus-8, inducible genetic knockdown, and cell-specific knockdown therapies.93,94 Fortunately, therapeutic efficacy is still demonstrable even when administered late in ALD in mice. Administration of heat-shock protein 90 inhibitor 17-DMAG prevented alcohol-induced liver injury when given directly before a binge of ethanol, but after 10 days of chronic alcohol treatment.95 By giving the drug at a point after chronic alcohol administration, the authors insured that the drug did not affect the onset of steatosis, but instead directly affected the immune dysfunction associated with binge on chronic alcohol treatment.95 Similar results with both prophylactic schemes and treatment schemes were obtained in a separate study investing the effect of pepducins on neutrophil recruitment in a model of moderate ASH.51 More studies testing late-stage therapeutics in addition to prophylactic treatment are recommended as they allow for the differentiation between effects on disease progression and effects on disease state.

A number of studies have recently begun validating their murine findings by following up in patients with ALD of varying degrees. Impressive results were recently obtained when investigators noticed that a protein called fat-specific protein 27 was up-regulated in microarray analysis of both human AH patients and mice fed an ASH-inducing diet.92 Up-regulation of the protein was confirmed in AH patients, and correlated with mortality and disease severity; however, knockout of the protein was protective in the mouse model, indicating direct involvement in the injury.92 As such, the study bridged the gap between murine ASH and human AH. Similarly, a study indicating expression of osteopontin in AH patients correlated with outcome and knockout of osteopontin was also protective in the mouse; although, contrary results were obtained in other alcohol models.49,90

These strategies may apply to diagnostic markers as well, as microRNA-192 was up-regulated in plasma samples of both mouse and humans exposed to alcohol, and was proposed as a potential diagnostic marker.96 “Humanizing” mice in an attempt to get a more human-like response from mice has also yielded interesting results. Fecal transfer between AH patients and germ-free or conventional mice resulted in a dramatic increase in susceptibility to ALD, indicating some microbiota may be inherently protective against ALD in patients that do not undergo progression to advanced steatohepatitis and subsequent disease states.97

Other studies have used treatment of primary human hepatocytes to determine how ethanol affects hepatocytes acutely in man. Treatment of primary human hepatocytes with ethanol resulted in posttranslational modifications of forkhead box protein Class O 3 (FOXO3) as seen with in vivo treatment of ethanol.98 Studies focused on validating murine results with direct human impact are integral to both our understanding of what the murine model represents and potential therapeutic targets in patients. Furthermore, these studies might elucidate novel information that assists in the development of high fidelity mouse models.

Induction of cirrhosis followed by administration of alcohol may also yield a better understanding of the effects of alcohol in populations with underlying liver disease. Cirrhosis of all origins, likely has more in common with AC than benign forms of murine ALD that feature consumption of alcohol. In support of this, patients with AC that remain abstinent for 6 months have limited steatosis, but still suffer from a number of associated complications and still have substantial neutrophil infiltrate in the liver.21 New models of cirrhosis that incorporate known effects of alcohol need to be developed.

While the effects of alcohol on naïve livers is well understood from decades of research, very few studies have examined the effects of alcohol on the cirrhotic liver. Administration of alcohol in addition to agents that can cause cirrhosis, such as repeated CCL4 injection, accelerates progression of disease by enhancing fibrosis.88 Chiang et al.12 hypothesized this was due to enhancement of the same pathways present in CCl4-treated mice; thus, agents that can dramatically enhance normal alcohol pathology may be useful. A number of knockout mouse models also experience fibrosis after chronic ethanol feeding. Given that only a minority of chronic alcohol drinkers undergo the conversion from steatosis to steatohepatitis, a genetic component may be involved, although little is understood about this area. Nevertheless, knockout mouse models with exacerbated effects should be validated in human patients when possible by assessing protein levels in patients at varying stages of ALD.

ALD – What does the future hold?

The number of studies on AH published has doubled in the years between 2006 and 2015, according to NCBI, and is continuing to increase at a rapid pace. As alcohol has widely been understudied relative to its impact on liver health, the field is poised for rapid expansion. During this period, it will be imperative to focus on development of legitimate models of late-stage ALD and AH if progress is to be made clinically on these fronts. Continued attempts at translating our understanding of the mouse to human patients using novel and innovative means will provide the greatest return, and will hopefully generate real therapeutics in the immediate future.

Abbreviations

AC: 

alcoholic cirrhosis

AH: 

alcoholic hepatitis

ALD: 

alcoholic liver disease

ALT: 

alanine aminotransferase

ASH: 

alcoholic steatohepatitis

AST: 

aspartate aminotransferase

CCL4

carbon tetrachloride

INR: 

international normalized ratio

LPS: 

lipopolysaccharide

ROS: 

reactive oxygen species

TJB: 

transjugular biopsy

TLR-4: 

toll-like receptor-4

TNF-α: 

tumor necrosis factor-α

Declarations

Acknowledgement

The work in the authors’ laboratory was supported in part by the National Institutes of Health grant R01 AA12916, the Robert Hanlon Trust, and grants from the National Institute of General Medical Sciences (P20 GM103549 and P30 GM118247) of the National Institutes of Health. Additional support came from the “Training Program in Environmental Toxicology” T32 ES007079-26A2 (to B.L.W.) from the National Institute of Environmental Health Sciences.

Conflict of interest

The authors have no conflict of interests related to this publication.

Authors’ contributions

Contributed to manuscript writing, manuscript conception (BLW), manuscript editing, manuscript conception (HJ).

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