Fifty years of pancreatic islet pathology in human type 1 diabetes: insights gained and progress made - Diabetologia

Historical perspectives

The concept that type 1 diabetes represents a specific disease with a unique aetiology only gained acceptance in the mid-1970s [1] although earlier pioneering studies (mainly by Willy Gepts in the 1960s [2]) had hinted at this conclusion by revealing some of the characteristic pancreatic pathology now known to define it. Progress has remained sluggish, however; largely because a meticulous examination of the target organ is not easily achieved in living individuals. Efforts are underway to improve non-invasive imaging [3] but, in humans, the pancreas remains largely inaccessible and surgical interventions still carry a serious risk. Useful rodent models have been developed to assist in defining the aetiology of type 1 diabetes [4,5,6] but there are fundamental differences between the rodent and human pancreas with respect to islet architecture [7], innervation [8, 9] and vasculature [8,9,10], which require caution to be exercised.

Looking back over the last 50 years, it is sobering to realise that fewer than 600 human pancreatic samples in total have been studied from people with type 1 diabetes or are available in pancreatic biobanks (Fig. 1; Table 1). Moreover, only a small subset of these come from young people with recent-onset disease. The largest collections are held in the Exeter Archival Diabetes Biobank (EADB) and the Network for Pancreatic Organ Donors with Diabetes (nPOD) [11]. The EADB is an archival collection comprised of predominantly post-mortem pancreas samples collected from young people (<20 years old) with recent-onset (<2 years) disease who died between 1935 and the mid-1990s [12]. Importantly, it contains the world’s largest collection of pancreas tissue from individuals diagnosed with diabetes under the age of 10 years (a comparison of the two largest collections is shown in Fig. 2; Table 2). However, most specimens were obtained post-mortem and the tissue is of variable quality such that its suitability for certain applications (e.g. RNA sequencing) is limited. By contrast, nPOD tissues are harvested and processed according to optimised standard operating procedures and samples are available for multiple applications [11, 13, 14]. Nevertheless, most nPOD pancreases come from older-onset donors with longer disease duration (Fig. 2; Table 2) and only a single organ is currently available from a donor under the age of 7 years with a short duration (<2 years) of disease. Newer initiatives, including the European INNODIA consortium and a Medical Research Council (MRC)-funded pancreas collection (the Quality in Organ Donation [QUOD] Biobank; coordinated from the University of Newcastle, UK) promise to deliver high-quality samples in the future. Further study of pancreas biobanks remains paramount for an improved understanding of diabetes [15].

Cumulative number of type 1 diabetes cases that have become available for study over the past 50 years. Fewer than 600 human pancreatic samples are available for study of the aetiopathology of type 1 diabetes in the various collections held across the world. Some form part of larger collections while other samples are cited only in specific publications (defined as ‘Publication’ in the key). These have been accumulated over time and the collection of samples is ongoing in the nPOD, European nPOD (EUnPOD), Nordic Network for Clinical Islet Transplantation and QUOD Biobank initiatives. Despite this, only a small subset of samples come from individuals with recent-onset (≤2 years) disease. DiViD, Diabetes Virus Detection Study. This figure is available as part of a downloadable slideset

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Comparison of pancreas samples available from donors with recent-onset (≤2 years) type 1 diabetes in the two largest collections available for study. Most of the pancreas samples available within the EADB (blue circles) come from individuals who were under the age of 20 years at diagnosis. Many had been diagnosed with type 1 diabetes for less than 6 months at the time of recovery of the gland. By contrast, those in the nPOD collection (red squares) were mainly older at onset. This figure is available as part of a downloadable slideset

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Islet structure and composition

In humans, islets are widely dispersed across the pancreas, although they may be present at higher density in the head and body of the organ than in the tail [16]. Each islet has a multicellular structure and, in rodent species, the beta cells are localised at the centre with the remaining endocrine cell types arranged in a peripheral ‘mantle’. In human islets, the beta and non-beta endocrine cells occur in a less structured conformation, particularly in larger islets [7, 16] (Fig. 3). Moreover, the proportions of the various endocrine cells are different between species, with a smaller overall percentage of beta cells (50–60%) in humans than in rodents [16, 17].

Cellular composition of a human islet of Langerhans from a healthy individual. Individual endocrine cell subtypes were identified by immunofluorescent analysis after staining with antisera directed against insulin (light blue), glucagon (red) and somatostatin (green). Cell nuclei were stained with DAPI (dark blue). Scale bar, 25 μm. The image was captured in our laboratory in Exeter and is from a case held in the EADB collection. This figure is available as part of a downloadable slideset

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Insulitis

An important advance arising from studies of the human pancreas in type 1 diabetes has been the description of insulitis, a process of immune cell infiltration into islets [18] (Fig. 4). This is also seen in animal models but insulitis is found at a lower frequency across the islet population in humans than in rodents, and the proportion of the various individual immune-cell subtypes differ between species (e.g. CD8⁺ T cells dominate human insulitis, whereas CD4⁺ cells are predominant in NOD mice). One note of caution, however, is that some evidence implies that the period spent in intensive care prior to organ recovery can influence the extent of immune-cell infiltration into the human pancreas [18].

Example of an inflamed islet from a child newly diagnosed with type 1 diabetes. Lymphocytes were immunostained in brown with an antibody directed against CD45. Small numbers of lymphocytes are found within the core of the islet but most are located peripherally, with the majority focused at one pole of the islet. Scale bar, 20 μm. The image was captured in our laboratory in Exeter and is from a case held in the EADB collection. This figure is available as part of a downloadable slideset

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Insulitis occurs mainly within the residual insulin-containing islets of people with recent-onset type 1 diabetes and many fewer insulin-deficient islets are inflamed [12, 19,20,21]. This implies that immune cells are recruited and retained primarily in response to factors emanating from their target beta cells, although the proportion of islets with inflammation varies, not simply in response to beta cell numbers, but also according to the age at disease onset. For example, among individuals diagnosed aged 13 years or older, the proportion of residual insulin-containing islets with insulitis is around 25%, whereas it is much higher (~80%) in those diagnosed in the very early years of life (<7 years of age) [22]. These statistics suggest that young children may have a more aggressive form of the disease. A further implication is that, among older individuals, functional insulin deficiency can occur despite the retention of a significant reserve of the hormone. This points not only to beta cell loss as a cause of type 1 diabetes, but also suggests an insulin-secretory dysfunction among the residual, non-inflamed islets in some individuals. These conclusions are supported by in vitro studies showing that the immediate post-isolation deficit in glucose-induced insulin secretion in the islets of people with type 1 diabetes may improve with time in culture [23].

The occurrence of insulitis is not restricted solely to the period immediately after disease onset but it can also be found in the insulin-containing islets of individuals with long-duration disease [21]. By contrast, it is less clear how long before diagnosis insulitis occurs in people who are progressing to disease. This is much more difficult to evaluate, of course, because prediction of disease onset is still an imperfect art. Nevertheless, it has proved so hard to uncover firm evidence of insulitis in individuals prior to disease onset that In’t Veld has defined the process as an ‘elusive lesion’ [21, 24,25,26].

Progression of insulitis

The relative difficulty in identifying insulitis in the human pancreas has led to the publication of an international consensus statement by which insulitis can be defined [27]. This represents a welcome advance since varying definitions have appeared in the literature over time [11, 19, 25, 28,29,30,31]. The consensus definition notes that ‘the lesion should be established in a minimum of three islets, with a threshold level of ≥15 CD45⁺ cells/islet before the diagnosis can be made’ [27, 32]. The utility of this statement has been challenged [33], but it remains an internationally accepted working definition [32].

Although the precise composition of the immune infiltrate is variable between islets and among individuals, important categories of insulitis have now been defined. In particular, in humans, CD8⁺ T cells are predominant, whereas CD4⁺ cells are often represented only as a minority population [19, 21, 34, 35]. In addition, the proportion of CD20⁺ cells (B cells) is variable [34,35,36] since, in very young children (≤7 years of age) these are present in relative abundance in inflamed islets, whereas their proportion is much lower in those who are older at diagnosis [34, 35]. The consequences of this difference (and the factors that underlie it) remain uncertain, but such variability must be considered when designing immunotherapeutic trials intended to reduce the rate of beta cell demise. In addition to lymphocytes, other immune-cell subtypes, including neutrophils [37], mast cells [38] and natural killer cells [39], have been reported to infiltrate the pancreas in, at least, some individuals with type 1 diabetes.

Work in the NOD mouse suggests the existence of sequential ‘stages’ of insulitis [40]; among these is a feature known as ‘peri-insulitis’ in which islets are surrounded by immune cells but not infiltrated by them. This is followed by more complete infiltration, where islets are invaded and the killing of beta cells occurs at high frequency. Equivalent stages are not seen in humans and invasive insulitis is detected only rarely. This suggests either that, in humans, the killing of beta cells is mediated by the very small number of immune (presumably CD8⁺) cells that penetrate into the endocrine cell milieu or, alternatively, that killing does not require direct contact between immune and beta cells. A third possibility also exists, in which the immune cells play (at best) only a minor role in beta cell death. In this context, recent evidence implies that many of the CD8⁺ cells present in insulitic lesions are resident memory cells, which lack a proinflammatory gene expression signature [41]. Nevertheless, it is also clear that some of the influent CD8⁺ T cells are reactive against islet antigens, suggesting an aggressive intent [42,43,44].

The histological feature referred to above termed ‘peri-insulitis’ mirrors most closely the arrangement of immune cells found in many inflamed islets in human type 1 diabetes. However, unlike the situation in NOD mice, where islets are surrounded by successive banks of lymphocytes, the influent immune cells are fewer in number in human islets and tend to adorn one of the poles [27, 45] (Fig. 4). This distribution suggests that immune cells are initially attracted to the islet environment but, on arrival, they encounter a barrier to entry. This is probably the ‘peri-islet membrane’, a structure that may require considerable re-modelling in order to permit immune cell entry.

Islet extracellular matrix

Islet chemokine expression

A key question that arises when considering the mechanisms by which immune cells might reach the islet, is the nature of the chemoattractant. It has been widely assumed that islets are induced to secrete chemokines during the initiation phase of beta cell destruction and that relevant immune cells then migrate to the source of these molecules. In support of this, several chemokines have been detected in inflamed islets, including, most frequently (but not exclusively [49]), the (C-X-C motif) ligand (CXCL)10 [50, 51]. This interacts with its cognate receptor, CXCR3, which has been detected on a subset of CD3⁺ cells present in immune infiltrates, including on a proinsulin-directed, autoreactive clone isolated from an individual with type 1 diabetes [50]. It is also known that beta cells can directly produce certain cytokines, including IL-1β [52], which might play a role in mediating their demise.

Islet HLA class I hyperexpression

Beta cell loss in type 1 diabetes

Conclusion

Our understanding of the aetiopathology of type 1 diabetes has advanced greatly since the pioneering studies by Gepts [2], mainly thanks to the opportunity to study additional rare and precious pancreas samples recovered from individuals with the disease. Nevertheless, the task is not complete and the more we look, the more the accepted wisdom is challenged. It is critical, therefore, that such work continues since only then will new opportunities for therapy and disease prevention emerge.

CXCL:

(C-X-C motif) ligand

EADB:

Exeter Archival Diabetes Biobank

MRC:

Medical Research Council

nPOD:

Network for Pancreatic Organ Donors with Diabetes

QUOD:

Quality in Organ Donation

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We are grateful for the contributions of many colleagues who have helped to identify the type 1 diabetes cases held within biobanks and/or reported in the literature. In particular, we are indebted to P. In’t Veld (Vrije Universiteit Brussel [VUB], Brussels); A. Foulis (GG&C Pathology Department, University of Glasgow, UK); M. Yang, M. Beery and A. Pugliese (nPOD, Miami & Gainesville, Florida, USA); J. Shaw (Institute of Cellular Medicine, University of Newcastle, UK); F. Dotta (Department of Medicine, Surgery and Neurosciences, University of Siena, Italy); and O. Skog (Department of Immunology, Genetics and Pathology, Uppsala University, Sweden). In addition, we would like to acknowledge the valuable work of other colleagues which has not been cited in this review due to space restrictions.

We are grateful for collaborative discussions with the Network for Pancreatic Organ donors with Diabetes (nPOD; RRID:SCR_014641), a collaborative type 1 diabetes research project sponsored by JDRF (nPOD: 5-SRA-2018-557-Q-R) and The Leona M. & Harry B. Helmsley Charitable Trust (Grant no. 2018PG-T1D053). Organ procurement organisations (OPO) partnering with nPOD to provide research resources are listed at www.jdrfnpod.org//for-partners/npod-partners/.

Authors and Affiliations

1. Islet Biology Exeter (IBEx), Institute of Biomedical and Clinical Science, University of Exeter Medical School, RILD Building (Level 4), Barrack Road, Exeter, EX2 5DW, UK

   Noel G. Morgan & Sarah J. Richardson

Contributions

Both NGM & SJR were responsible for drafting the article and revising it critically for important intellectual content. Both authors approved the version to be published.

Corresponding author

Correspondence to Noel G. Morgan.

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