Neil D. Theise

Multi-Organ, Multi-Lineage Engraftment by a Single Bone Marrow-Derived Stem Cell

Purification of rare hematopoietic stem cell(s) (HSC) to homogeneity is required to study their self-renewal, differentiation, phenotype, and homing. Long-term repopulation (LTR) of irradiated hosts and serial transplantation to secondary hosts represent the gold standard for demonstrating self-renewal and differentiation, the defining properties of HSC. We show that rare cells that home to bone marrow can LTR primary and secondary recipients. During the homing, CD34 and SCA-1 expression increases uniquely on cells that home to marrow. These adult bone marrow cells have tremendous differentiative capacity as they can also differentiate into epithelial cells of the liver, lung, GI tract, and skin. This finding may contribute to clinical treatment of genetic disease or tissue repair.

Cell plasticity: flexible arrangement.

Elucidation of all of the mechanisms that regulate developmental potential will allow us to discover the true limits of cell differentiation.

Signalling via the osteopontin and high mobility group box-1 axis drives the fibrogenic response to liver injury

Objective Liver fibrosis is associated with significant collagen-I deposition largely produced by activated hepatic stellate cells (HSCs); yet, the link between hepatocyte damage and the HSC profibrogenic response remains unclear. Here we show significant induction of osteopontin (OPN) and high-mobility group box-1 (HMGB1) in liver fibrosis. Since OPN was identified as upstream of HMGB1, we hypothesised that OPN could participate in the pathogenesis of liver fibrosis by increasing HMGB1 to upregulate collagen-I expression. Design and results Patients with long-term hepatitis C virus (HCV) progressing in disease stage displayed enhanced hepatic OPN and HMGB1 immunostaining, which correlated with fibrosis stage, whereas it remained similar in non-progressors. Hepatocyte cytoplasmic OPN and HMGB1 expression was significant while loss of nuclear HMGB1 occurred in patients with HCV-induced fibrosis compared with healthy explants. Well-established liver fibrosis along with marked induction of HMGB1 occurred in CCl4-injected OpnHep transgenic yet it was less in wild type and almost absent in Opn−/− mice. Hmgb1 ablation in hepatocytes (Hmgb1ΔHep) protected mice from CCl4-induced liver fibrosis. Coculture with hepatocytes that secrete OPN plus HMGB1 and challenge with recombinant OPN (rOPN) or HMGB1 (rHMGB1) enhanced collagen-I expression in HSCs, which was blunted by neutralising antibodies (Abs) and by Opn or Hmgb1 ablation. rOPN induced acetylation of HMGB1 in HSCs due to increased NADPH oxidase activity and the associated decrease in histone deacetylases 1/2 leading to upregulation of collagen-I. Last, rHMGB1 signalled via receptor for advanced glycation end-products and activated the PI3K–pAkt1/2/3 pathway to upregulate collagen-I. Conclusions During liver fibrosis, the increase in OPN induces HMGB1, which acts as a downstream alarmin driving collagen-I synthesis in HSCs.

Mixed adenoneuroendocrine carcinoma (MANEC) of the gallbladder: a possible stem cell tumor?

A 48 year‐old African American woman presented to her physician complaining of a rapidly evolving epigastric and right upper quadrant abdominal pain. A PET‐CT of the abdomen and pelvis demonstrated hypermetabolic, polypoid masses within the gallbladder and several tumors in the left lobe of the liver for which she underwent diagnostic laparoscopy. The gallbladder revealed a 3.5 × 3.3 × 2.4 tan‐brown exophytic mass located at the fundus and growing into the lumen with multiple contiguous papillary projections arising from the mucosal surface. A concurrent large cell neuroendocrine carcinoma and papillary adenocarcinoma of the gallbladder was revealed histologically. There was shared reactivity to antibodies directed against the distinct antigens for each morphological component with transitional tumor cells (of both histological components) located at the areas where the two tumor types merged, revealing common immunoreactivity for carcinoembryonic antigen, cancer antigen 19‐9, keratin 19, c‐kit (cluster of differentiation protein 117 (CD117)) and epithelial cell adhesion molecule. Ultrastructurally, individual cells were demonstrated to have overlapping features of neuroendocrine and glandular differentiation. The aforementioned histological, ultrastructural and immunohistochemical profile is strongly suggestive of a biphenotypic stem/progenitor cell tumor of the gallbladder.

Hepatic expression of toll-like receptors 3, 4, and 9 in primary biliary cirrhosis and chronic hepatitis C

UNLABELLED Toll-like receptors (TLRs) may play a role in the inflammatory patterns observed in primary biliary cirrhosis (PBC) and chronic hepatitis C (CHC). We investigated TLR 3, 4 and 9 expression in PBC and CHC using immunohistochemical staining. METHODS Patient biopsies of PBC (N=11) and CHC (N=15) were compared to disease free livers (n=7). The extent of TLR staining was assessed separately according to a semi-quantitative scale for hepatocytes, cholangiocytes and portal mononuclear cells (PMC). RESULTS In hepatocytes, TLR4 expression was increased (PBC; P=0.019), as was TLR9 (PBC; P=0.006, CHC; P=0.001). Cholangiocyte expression of TLRs 4 and 3 was reduced in both PBC (TLR4; P<0.0001, TLR3; P=0.006) and CHC (TLR4; P<0.0001, TLR3; P=0.014). Cholangiocyte expression of TLR9 was elevated for both groups and was significant in CHC (P=0.0115). PMCs showed up-regulation of TLR9 in PBC (P=0.022) and CHC (P=0.0001), with almost no expression of TLR 3 or 4. CONCLUSIONS In PBC and CHC, hepatocytes showed increased TLR 4 and 9 expression without change in TLR3. Cholangiocytes showed increased TLR9 expression as opposed to down-regulation of TLRs 3 and 4. PMCs in both diseases had significantly increased TLR 9 expression perhaps implicating TLR9 expression in chronic liver inflammation.

Necrotizing Granulomatous Hepatitis as an Unusual Manifestation of Lyme Disease

Lyme disease is the most common vector-borne infection in the United States and is caused by Borrelia burgdorferi, a spirochete that is transmitted from the ixodid tick. Abnormal liver chemistry is a rare, but well-described phenomenon in Lyme disease infection [1]. There have been several postulated theories as to the cause of hepatitis with B. burgdorferi infection. These include direct toxicity from the spirochete, systemic cytokine release, and, possibly, an immune-mediated event [2]. Although elevated aminotransferase has been seen, there has been only one case reported of granulomatous hepatitis from Lyme infection [3]. We describe here the first case of a patient with acute Lyme disease who was found to have necrotizing granulomatous hepatitis with eosinophilic infiltration of the liver.

Stem Cell Research: Elephants in the Room

The degree to which these elephants are disruptive to the steady advancement of the adult stem cell field will become clear with time. In some ways they enliven the discourse, but in many ways they interfere with efficient progress. Naming these elephants is a first step toward dealing with them. If we remain aware of these issues when evaluating new research, we are less likely to make careless mistakes, and we are more likely to be able to hold scientists, politicians, journalists, and entrepreneurs accountable for their practices. Although all adult stem cell researchers will spend time profitably riding some of these elephants, we will all inevitably spend more time cleaning up after them. Perhaps open, careful, and unbiased discussions of these elephants will help the cleanup work be less odious and completed sooner, rather than later.

Liver stem cells: prospects for treatment of inherited and acquired liver diseases.

It is now understood that there are three cell compartments which physiologically contribute to vertebrate liver parenchymal maintenance and regeneration after injury: mature liver cells (hepatocytes, cholangiocytes), intraorgan stem/progenitor cells (cells of the proximal biliary tree, periductal cells) and extraorgan stem cells (from the circulation and the bone marrow). All of these cell populations, as well as other, non-physiologic stem cells (e.g., mesenchymal stromal cells from the bone marrow, fetal hepatoblasts, embryonic stem [ES] cells), may be used therapeutically for treatment of inherited and acquired liver diseases. This article will summarise our current understanding of these various cell populations, and review possible approaches to their therapeutic use, including cell transplantation, bioartificial liver devices (BLDs), gene therapy and administration of exogenous factors to stimulate normal physiological responses to repair.

Hepatic steatosis estimated microscopically versus digital image analysis.

Evaluate in liver biopsies: (i) interobserver agreement of estimates of fat proportionate area (eFPA) and steatosis grading, (ii) the relationship between steatosis grades and measured fat proportionate area (mFPA, digital image analysis), (iii) the accuracy of eFPA, (iv) to present images to aid standardization and accuracy of eFPA.

Chimeric mice reveal clonal development of pancreatic acini, but not islets

Intestinal crypt stem cells establish clonal descendants. To determine whether the pancreas is patterned by a similar process, we used embryonic stem (ES) cell chimeric mice, in which male ES cells were injected into female blastocysts. Fluorescence in situ hybridization for the Y chromosome (Y-FISH) revealed clonal patterning of ES-derived cells in the adult mouse small intestine and pancreas. Intestinal crypts were entirely male or entirely female. Villi contained columns of male or female epithelial cells, consistent with upward migration of cells from the crypts which surround them. Within the exocrine pancreas, acini were entirely male or entirely female, consistent with patterning from a single stem/progenitor cell. Pancreatic islets contained a mixture of male and female cells, consistent with patterning from multiple progenitors. Male-female chimeric mice demonstrate that the adult mouse exocrine pancreatic acinus is patterned from a single stem/progenitor cell, while the endocrine pancreas arises from multiple progenitors.