Cell proliferation in a peripheral target is required for the induction of central neurogenesis in the leech

Several days after the completion of the early phase of cell proliferation that generates most of the leech central nervous system, the pair of “sex ganglia” in the two reproductive segments of the midbody undergo a second period of neurogenesis that gives rise to several hundred peripherally induced central (PIC) neurons. This proliferative phase, which begins on embryonic day 17 (E17), is induced by the interaction of a few specific neurons in the sex ganglia with a peripheral target, the male genitalia, during a critical period that extends from E13 to E16. The central nervous system (CNS) determines the critical period, since the male genitalia have the capacity to induce PIC neurons beginning on E10 and continuing throughout embryogenesis. Here we first show, by injecting hydroxyurea into staged embryos to ablate dividing cells, that PIC neuron precursors begin to divide at a low rate before E17, during the critical period. Then, through a series of homochronic and heterochronic male organ transplantations combined with hydroxyurea treatment of hosts and/or donors, we show that cell proliferation is required in the target itself for it to be competent to induce PIC neurons. These observations demonstrate that a nerve connection can couple cell proliferation in a peripheral target to cell proliferation in the CNS, providing a novel means for size adjustment of a central neuronal population relative to a peripheral target. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 295–303, 1998     

The interleukin-1β converting enzyme family of cysteine proteases

Interleukin-1β converting enzyme (ICE) is the first enzyme of a new family of cysteine endoproteinases to be isolated and characterized. An overview of the structure and activity of ICE is outlined together with highlights of salient features common to members of each of the family members. J. Cell. Biochem. 64:2–10. © 1997 Wiley-Liss, Inc.     

Unsupervised discovery of dynamic cell phenotypic states from transmitted light movies

Identification of cell phenotypic states within heterogeneous populations, along with elucidation of their switching dynamics, is a central challenge in modern biology. Conventional single-cell analysis methods typically provide only indirect, static phenotypic readouts. Transmitted light images, on the other hand, provide direct morphological readouts and can be acquired over time to provide a rich data source for dynamic cell phenotypic state identification. Here, we describe an end-to-end deep learning platform, UPSIDE (Unsupervised Phenotypic State IDEntification), for discovering cell states and their dynamics from transmitted light movies. UPSIDE uses the variational auto-encoder architecture to learn latent cell representations, which are then clustered for state identification, decoded for feature interpretation, and linked across movie frames for transition rate inference. Using UPSIDE, we identified distinct blood cell types in a heterogeneous dataset. We then analyzed movies of patient-derived acute myeloid leukemia cells, from which we identified stem-cell associated morphological states as well as the transition rates to and from these states. UPSIDE opens up the use of transmitted light movies for systematic exploration of cell state heterogeneity and dynamics in biology and medicine.     

Activation, regulation, and inhibition of DYRK1A

Dual-specificity tyrosine phosphorylation-regulated kinase 1A (DYRK1A) is a protein kinase with diverse functions in neuronal development and adult brain physiology. Higher than normal levels of DYRK1A are associated with the pathology of neurodegenerative diseases and have been implicated in some neurobiological alterations of Down syndrome, such as mental retardation. It is therefore important to understand the molecular mechanisms that control the activity of DYRK1A. Here we review the current knowledge about the initial self-activation of DYRK1A by tyrosine autophosphorylation and propose that this mechanism presents an ancestral feature of the CMGC group of kinases. However, tyrosine phosphorylation does not appear to regulate the enzymatic activity of DYRK1A. Control of DYRK1A may take place on the level of gene expression, interaction with regulatory proteins and regulated nuclear translocation. Finally, we compare the properties of small molecule inhibitors that target DYRK1A and evaluate their potential application and limitations. The β-carboline alkaloid harmine is currently the most selective and potent inhibitor of DYRK1A and has proven very useful in cellular assays.     

Binding characteristics and cross-reactivity of three different antilipid A monoclonal antibodies

A detailed characterization of binding specificity and cross-reactivity of three antilipid A murine mAb was performed. Binding characteristics of these three mAb were investigated against Ag (ReLPS, lipid A, derivatives of lipid A) in solid phase (ELISA) and in fluid phase (C consumption, inhibition studies), and upon incorporation in membranes (E: passive hemolysis assay, and liposomes: inhibition studies). Cross-reactivity with heterologous Ag was investigated in ELISA (LPS, Gram-negative bacteria) and immunoblot experiments (LPS). The binding specificity of mAb 26-5 (IgG2b), raised against synthetic lipid A, was located in the hydrophilic region of biphospholipid A and was also exposed after membrane incorporation of lipid A or after preincubation of lipid A with polymyxin B (PMX). mAb 26-20 (IgM), also raised against synthetic lipid A, showed binding specificity for the hydrophobic region of lipid A: no binding to membrane-associated lipid A could be demonstrated, and binding in ELISA could be blocked very efficiently by PMX. The reaction pattern of mAb 8-2 (IgM), raised against the heat-killed Re mutant of Salmonella typhimurium, was in part similar to that of mAb 26-20. However, inhibition of binding with PMX was less efficient and a high specificity for ReLPS, also after membrane incorporation of this Ag, was demonstrated. In contrast to mAb 26-5 and 26-20, mAb 8-2 showed extensive cross-reactivity with heterologous LPS preparations and heat-killed as well as live Gram-negative bacteria. It is concluded that each of the three mAb binds to a different antigenic epitope in lipid A and that exposure of those epitopes for antibody binding is restricted in a differential manner, depending on mode of Ag presentation. The here defined reaction patterns provide a basis for the interpretation of potential inhibitory effects on in vitro and in vivo biologic (and toxic) activities of endotoxins and Gram-negative bacteria.     

Andes Virus Recognition of Human and Syrian Hamster β3 Integrins Is Determined by an L33P Substitution in the PSI Domain

Andes virus (ANDV) causes a fatal hantavirus pulmonary syndrome (HPS) in humans and Syrian hamsters. Human α_vβ₃ integrins are receptors for several pathogenic hantaviruses, and the function of α_vβ₃ integrins on endothelial cells suggests a role for α_vβ₃ in hantavirus directed vascular permeability. We determined here that ANDV infection of human endothelial cells or Syrian hamster-derived BHK-21 cells was selectively inhibited by the high-affinity α_vβ₃ integrin ligand vitronectin and by antibodies to α_vβ₃ integrins. Further, antibodies to the β₃ integrin PSI domain, as well as PSI domain polypeptides derived from human and Syrian hamster β₃ subunits, but not murine or bovine β₃, inhibited ANDV infection of both BHK-21 and human endothelial cells. These findings suggest that ANDV interacts with β₃ subunits through PSI domain residues conserved in both Syrian hamster and human β₃ integrins. Sequencing the Syrian hamster β₃ integrin PSI domain revealed eight differences between Syrian hamster and human β₃ integrins. Analysis of residues within the PSI domains of human, Syrian hamster, murine, and bovine β₃ integrins identified unique proline substitutions at residues 32 and 33 of murine and bovine PSI domains that could determine ANDV recognition. Mutagenizing the human β₃ PSI domain to contain the L33P substitution present in bovine β₃ integrin abolished the ability of the PSI domain to inhibit ANDV infectivity. Conversely, mutagenizing either the bovine PSI domain, P33L, or the murine PSI domain, S32P, to the residue present human β₃ permitted PSI mutants to inhibit ANDV infection. Similarly, CHO cells transfected with the full-length bovine β₃ integrin containing the P33L mutation permitted infection by ANDV. These findings indicate that human and Syrian hamster α_vβ₃ integrins are key receptors for ANDV and that specific residues within the β₃ integrin PSI domain are required for ANDV infection. Since L33P is a naturally occurring human β₃ polymorphism, these findings further suggest the importance of specific β₃ integrin residues in hantavirus infection. These findings rationalize determining the role of β₃ integrins in hantavirus pathogenesis in the Syrian hamster model.Hantaviruses persistently infect specific small mammal hosts and are spread to humans by the inhalation of aerosolized excreted virus (41, 42). Hantaviruses predominantly infect endothelial cells and cause one of two vascular leak-based diseases: hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS) (41). Hantavirus diseases are characterized by increased vascular permeability and acute thrombocytopenia in the absence of endothelial cell lysis (36, 41, 42, 54). In general, hantaviruses are not spread from person to person; however, the Andes hantavirus (ANDV) is an exception, since there are several reports of person-to-person transmission of ANDV infection (11, 37, 47, 52). ANDV is also unique in its ability to cause an HPS-like disease in Syrian hamsters and serves as the best-characterized hantavirus disease model with a long onset, symptoms, and pathogenesis nearly identical to that of HPS patients (20, 21, 50).Hantavirus infection of the endothelium alters endothelial cell barrier functions through direct and immunological responses (8, 14). Although the means by which hantaviruses cause pulmonary edema or hemorrhagic disease has been widely conjectured, the mechanisms by which hantaviruses elicit pathogenic human responses have yet to be defined. Hantaviruses coat the surface of infected VeroE6 cells days after infection (17), and this further suggests that dynamic hantavirus interactions with immune and endothelial cells are likely to contribute to viral pathogenesis. Hantavirus pathogenesis has been suggested to involve CD8⁺ T cells, tumor necrosis factor alpha or other cytokines, viremia, and the dysregulation of β₃ integrins (7, 8, 13-16, 25-28, 32, 34, 38, 44-46). However, these responses have not been demonstrated to contribute to hantavirus pathogenesis, and in some cases there are conflicting data on their involvement (18, 25-28, 34, 35, 44, 45, 48). Immune complex deposition clearly contributes to HFRS patient disease and renal sequelae (4, 7), but it is unclear what triggers vascular permeability in HPS and HFRS diseases or why hemorrhage occurs in HFRS patients but not in HPS patients (8, 36, 54). Acute thrombocytopenia is common to both diseases, and platelet dysfunction resulting from defective platelet aggregation is reported in HFRS patients (7, 8).Pathogenic hantaviruses have in common their ability to interact with α_IIbβ₃ and α_vβ₃ integrins present on platelets and endothelial cells (13, 16), and β₃ integrins have primary roles in regulating vascular integrity (1, 2, 6, 19, 22, 39, 40). Consistent with the presence of cell surface displayed virus (17), pathogenic hantaviruses uniquely block α_vβ₃ directed endothelial cell migration and enhance endothelial cell permeability for 3 to 5 days postinfection (14, 15). Pathogenic hantaviruses dysregulate β₃ integrin functions by binding domains present at the apex of inactive β₃ integrin conformers (38). α_vβ₃ forms a complex with vascular endothelial cell growth factor receptor 2 (VEGFR2) and normally regulates VEGF-directed endothelial cell permeability (2, 3, 10, 39, 40). However, both β₃ integrin knockouts and hantavirus-infected endothelial cells result in increased VEGF-induced permeability, presumably by disrupting VEGFR2-β₃ integrin complex formation (2, 14, 19, 39, 40). This suggests that at least one means for hantaviruses to increase vascular permeability occurs through interactions with β₃ integrins that are required for normal platelet and endothelial cell functions.α_vβ₃ and α_IIbβ₃ integrins exist in two conformations: an active extended conformation where the ligand binding head domain is present at the apex of the heterodimer and a basal, inactive bent conformation where the globular head of the integrin is folded toward the cell membrane (30, 53, 55). Pathogenic HTN and NY-1 hantaviruses bind to the N-terminal plexin-semaphorin-integrin (PSI) domain of β₃ integrin subunits and are selective for bent, inactive α_vβ₃ integrin conformers (38). Pathogenic hantavirus binding to inactive α_vβ₃ integrins is consistent with the selective inhibitory effect of hantaviruses on α_vβ₃ function and endothelial cell permeability (14, 15, 38). Although the mechanism of hantavirus induced vascular permeability has yet to be defined, there is a clear role for β₃ integrin dysfunction in vascular permeability deficits (5, 6, 22, 29, 39, 40, 51) which make an understanding of hantavirus interactions with β₃ subunits important for both entry and disease processes.The similarity between HPS disease in humans and Syrian hamsters (20, 21) suggests that pathogenic mechanisms of ANDV disease are likely to be coincident. Curiously, other hantaviruses (Sin Nombre virus [SNV] and Hantaan virus [HTNV]) are restricted in Syrian hamsters and fail to cause disease in this animal, even though they are prominent causes of human disease (50). Although the host range restriction for SNV and HTNV in Syrian hamsters has not been defined (33), the pathogenesis of ANDV in Syrian hamsters suggests that both human and Syrian hamster β₃ integrins may similarly be used by ANDV and contribute to pathogenesis.We demonstrate here that ANDV infection of the Syrian hamster BHK-21 cell line and human endothelial cells is dependent on α_vβ₃ and inhibited by α_vβ₃ specific ligands and antibodies. Further, polypeptides expressing the N-terminal 53 residues of human and Syrian hamster β₃ subunits block ANDV infection. This further indicates that ANDV interaction with the N-terminal 53 residues of both human and Syrian hamster β₃ integrins is required for viral entry. We also demonstrate that ANDV recognition of human and Syrian hamster β₃ integrins is determined by proline substitutions at residues 32/33 within the β₃ integrin PSI domain. These results define unique ANDV interactions with human and Syrian hamster β₃ integrins.     

Within-pair testosterone covariation and reproductive output in Greylag Geese Anser anser

In monogamous animals, reproductive success may vary considerably among pairs. To study this variation, we focussed on reproductive events and the circannual hormonal co-ordination within pairs during the reproductive cycle. Testosterone was chosen as covariable for both sexes because of its mediator function between behaviour and physiology. In a flock of free-living Greylag Geese Anser anser , individual faecal samples were collected weekly from 23 pairs over a complete annual cycle. From the faeces, equivalents of testosterone, oestrogen and other steroid hormones were analysed by enzyme immunoassay. In contrast to correlations between male and female testosterone, no correlations were found between oestrogen-oestrogen or oestrogen-testosterone. Therefore, only testosterone (T) is considered here. Sex-specific differences in T were in amplitude rather than in the annual timing of maxima and minima. However, the annual timing varied to some degree between individuals within sexes. Therefore, we examined the degree of annual testosterone correlation (TC) within pairs. Pairs that nested had significantly higher TC over the year than pairs that did not. The higher the within-pair TC, the larger the clutches and the heavier the eggs. Also, TC in the year investigated was positively and significantly correlated with the pairs' long-term reproductive output. No correlation was found between TC and the duration of the pair-bond, individual age, or age difference from pair partner. We suggest that TC is a measure of behavioural synchrony and, therefore, pair-bond quality. We consider whether within-pair TC results from mate choice.