Distinct roles for adhesion molecules during innervation of embryonic chick muscle

In vitro studies have suggested that the cell adhesion molecules NCAM and G4/L1 contribute to a variety of events during neural development. We have directly tested the role played by these molecules in the process of initial nerve ingrowth and ramification in the embryonic chick iliofibularis muscle by in ovo injections of specific adhesion-blocking antibodies and analysis of the resultant nerve branching pattern in muscle whole mounts. Antibodies against both molecules produced axonal defasciculation, which resulted in an enhanced transverse projection to the fast region of the muscle. In the case of anti-G4/L1, we also observed a large increase in the number of side branches that form from nerve trunks in the slow region and an enhancement of nerve branching in the fast region. Conversely, anti-NCAM produced a striking decrease in both the number and length of side branches in the slow region, and a reduction in nerve branching in the fast region. A similar reduction of nerve branching was obtained following injection of an endosialidase, which removes sialic acid from NCAM, and which was observed to enhance fiber-fiber apposition, presumably by increasing cell adhesion. Based on their biochemical properties in vitro and their in vivo distribution, both NCAM and G4/L1 are in a position to contribute to axon-axon adhesive interactions, whereas NCAM would be expected to also promote axon-myotube interactions. Our observations in fact indicate that these two adhesion molecules play different but complementary roles during muscle innervation and, specifically, that axon-axon fasciculation is influenced by both NCAM and G4/L1 in an anatomically distinct manner to regulate the overall pattern of nerve branching and that NCAM-mediated axon-myotube interactions are necessary for the attainment of the normal stereotyped pattern of nerve branching in both fast and slow regions of this muscle.     

Distinct roles for visceral endoderm during embryonic mouse development.

The murine visceral endoderm is an extraembryonic cell layer that appears prior to gastrulation and performs critical functions during embryogenesis. The traditional role ascribed to the visceral endoderm entails nutrient uptake and transport. Besides synthesizing a number of specialized proteins that facilitate uptake, digestion, and secretion of nutrients, the extraembryonic visceral endoderm coordinates blood cell differentiation and vessel formation in the adjoining mesoderm, thereby facilitating efficient exchange of nutrients and gases between the mother and embryo. Recent studies suggest that in addition to this nutrient exchange function the visceral endoderm overlying the egg cylinder stage embryo plays an active role in guiding early development. Cells in the anterior visceral endoderm function as an early organizer. Prior to formation of the primitive streak, these cells express specific gene products that specify the fate of underlying embryonic tissues. In this review we highlight recent investigations demonstrating this dual role for visceral endoderm as a provider of both nutrients and developmental cues for the early embryo.     

Distinct roles of DMAP1 in mouse development

DMAP1 (DNMT1-associated protein 1) is a member of the TIP60-p400 complex that maintains embryonic stem (ES) cell pluripotency and a complex containing the somatic form of DNA methyltransferase 1 (DNMT1s). DMAP1 interacts with DNMT1s through a domain that is absent in Dnmt1(V)(/)(V) mice expressing just the oocyte form (DNMT1o). A Dmap1-null allele was generated to study the role of DMAP1 in development. Consistent with the phenotypes of loss of other members of the TIP60-p400 complex, Dmap1(-/-) mice died during preimplantation in both Dnmt1(+/+) and Dnmt1(V)(/)(V) backgrounds. Unexpectedly, in the Dnmt1(V)(/)(V) background, Dmap1(+/-) parents produced mainly Dmap1(+/-) mice. Most Dmap1(+/+) progeny died during midgestation, with loss of DNA methylation on imprinted genes, suggesting that DMAP1 influences maintenance methylation mediated by DNMT1o. In this regard, a DMAP1-DNMT1o complex was detected in ES cells when DNMT1o was stably expressed but not when transiently expressed, indicating a novel interaction between DMAP1 and DNMT1o. These results suggest that DMAP1-DNMT1s and DMAP1-DNMT1o interactions are essential for normal development and that DMAP1-DNMT1o complexes are not readily formed in the embryo. Therefore, DMAP1 mediates distinct preimplantation epigenetic reprogramming processes: TIP60-p400 nucleosome remodeling and DNMT1 maintenance methylation.     

Distinct roles of beta1 integrins during angiogenesis

Integrins are transmembrane receptors which bind extracellular matrix proteins and enable not only cell adhesion and cytoskeleton organization but also transduction of critical signals into the cells to promote survival, proliferation, differentiation, or migration programs. Integrins participate in many aspects of vascular biology. The past few years have experienced a sustained interest in the implication of integrin receptors in tumor angiogenesis. We will focus our review on studies giving concrete evidence to a role of the beta1 class of integrins in angiogenesis, and we will provide an overview of the molecular mechanisms involved in their action.     

Distinct roles for ERK1 and ERK2 in pathophysiology of CNS

Mitogen-activated protein kinases ERK1 and ERK2 have been implicated in various pathophysiological events of the CNS,but their specific roles in cell processes under physiologic and pathological condit...     

Distinct roles for RDE-1 and RDE-4 during RNA interference in Caenorhabditis elegans.

RNA interference (RNAi) is a cellular defense mechanism that uses double-stranded RNA (dsRNA) as a sequence-specific trigger to guide the degradation of homologous single-stranded RNAs. RNAi is a multistep process involving several proteins and at least one type of RNA intermediate, a population of small 21-25 nt RNAs (called siRNAs) that are initially derived from cleavage of the dsRNA trigger. Genetic screens in Caenorhabditis elegans have identified numerous mutations that cause partial or complete loss of RNAi. In this work, we analyzed cleavage of injected dsRNA to produce the initial siRNA population in animals mutant for rde-1 and rde-4, two genes that are essential for RNAi but that are not required for organismal viability or fertility. Our results suggest distinct roles for RDE-1 and RDE-4 in the interference process. Although null mutants lacking rde-1 show no phenotypic response to dsRNA, the amount of siRNAs generated from an injected dsRNA trigger was comparable to that of wild-type. By contrast, mutations in rde-4 substantially reduced the population of siRNAs derived from an injected dsRNA trigger. Injection of chemically synthesized 24- or 25-nt siRNAs could circumvent RNAi resistance in rde-4 mutants, whereas no bypass was observed in rde-1 mutants. These results support a model in which RDE-4 is involved before or during production of siRNAs, whereas RDE-1 acts after the siRNAs have been formed.     

Distinct roles for ROCK1 and ROCK2 in the regulation of cell detachment

This study, using mouse embryonic fibroblast (MEF) cells derived from ROCK1^−/− and ROCK2^−/− mice, is designed to dissect roles for ROCK1 and ROCK2 in regulating actin cytoskeleton reorganization induced by doxorubicin, a chemotherapeutic drug. ROCK1^−/− MEFs exhibited improved actin cytoskeleton stability characterized by attenuated periphery actomyosin ring formation and preserved central stress fibers, associated with decreased myosin light chain 2 (MLC2) phosphorylation but preserved cofilin phosphorylation. These effects resulted in a significant reduction in cell shrinkage, detachment, and predetachment apoptosis. In contrast, ROCK2^−/− MEFs showed increased periphery membrane folding and impaired cell adhesion, associated with reduced phosphorylation of both MLC2 and cofilin. Treatment with inhibitor of myosin (blebbistatin), inhibitor of actin polymerization (cytochalasin D), and ROCK pan-inhibitor (Y27632) confirmed the contributions of actomyosin contraction and stress fiber instability to stress-induced actin cytoskeleton reorganization. These results support a novel concept that ROCK1 is involved in destabilizing actin cytoskeleton through regulating MLC2 phosphorylation and peripheral actomyosin contraction, whereas ROCK2 is required for stabilizing actin cytoskeleton through regulating cofilin phosphorylation. Consequently, ROCK1 and ROCK2 can be functional different in regulating stress-induced stress fiber disassembly and cell detachment.     

Distinct spatiotemporal roles of hedgehog signalling during chick and mouse cranial base and axial skeleton development

The cranial base exerts a supportive role for the brain and includes the occipital, sphenoid and ethmoid bones that arise from cartilaginous precursors in the early embryo. As the occipital bone and the posterior part of the sphenoid are mesoderm derivatives that arise in close proximity to the notochord and floor plate, it has been assumed that their development, like the axial skeleton, is dependent on Sonic hedgehog (Shh) and modulation of bone morphogenetic protein (Bmp) signalling. Here we examined the development of the cranial base in chick and mouse embryos to compare the molecular signals that are required for chondrogenic induction in the trunk and head. We found that Shh signalling is required but the molecular network controlling cranial base development is distinct from that in the trunk. In the absence of Shh, the presumptive cranial base did not undergo chondrogenic commitment as determined by the loss of Sox9 expression and there was a decrease in cell survival. In contrast, induction of the otic capsule occurred normally demonstrating that induction of the cranial base is uncoupled from formation of the sensory capsules. Lastly, we found that the early cranial mesoderm is refractory to Shh signalling, likely accounting for why development of the cranial base occurs after the axial skeleton. Our data reveal that cranial and axial skeletal induction is controlled by conserved, yet spatiotemporally distinct mechanisms that co-ordinate development of the cranial base with that of the cranial musculature and the pharyngeal arches.     

Distinct roles for intra- and extracellular siderophores during Aspergillus fumigatus infection

Siderophore biosynthesis by the highly lethal mould Aspergillus fumigatus is essential for virulence, but non-existent in humans, presenting a rare opportunity to strategize therapeutically against this pathogen. We have previously demonstrated that A. fumigatus excretes fusarinine C and triacetylfusarinine C to capture extracellular iron, and uses ferricrocin for hyphal iron storage. Here, we delineate pathways of intra- and extracellular siderophore biosynthesis and show that A. fumigatus synthesizes a developmentally regulated fourth siderophore, termed hydroxyferricrocin, employed for conidial iron storage. By inactivation of the nonribosomal peptide synthetase SidC, we demonstrate that the intracellular siderophores are required for germ tube formation, asexual sporulation, resistance to oxidative stress, catalase A activity, and virulence. Restoration of the conidial hydroxyferricrocin content partially rescues the virulence of the apathogenic siderophore null mutant Delta sidA, demonstrating an important role for the conidial siderophore during initiation of infection. Abrogation of extracellular siderophore biosynthesis following inactivation of the acyl transferase SidF or the nonribosomal peptide synthetase SidD leads to complete dependence upon reductive iron assimilation for growth under iron-limiting conditions, partial sensitivity to oxidative stress, and significantly reduced virulence, despite normal germ tube formation. Our findings reveal distinct cellular and disease-related roles for intra- and extracellular siderophores during mammalian Aspergillus infection.     

Distinct roles for Rev1p and Rev7p during translesion synthesis in Saccharomyces cerevisiae

Translesion synthesis (TLS) in Saccharomyces cerevisiae requires at least Rev1p and polymerase zeta (Pol zeta), a complex of the Rev3 polymerase and its accessory factor Rev7p. Although their precise role(s) are poorly characterized, in vitro studies suggest that each protein contributes to TLS in a manner dependent on the particular lesion and surrounding DNA sequence. In the present study, strand segregation analysis is used to attempt to identify the role(s) of the Rev1 and Rev7 proteins during TLS. This assay uses double-stranded plasmids containing a genetic marker opposite to a replication blocking lesion (N-2-acetylaminofluorene; AAF) to measure TLS quantitatively and qualitatively in vivo. The AAF adduct is localized within a repetitive sequence in a manner that allows the formation of misaligned primer-template replication intermediates. Elongation from a misaligned intermediate fixes a frameshift mutation (slipped TLS), while extension of the correctly aligned lesion terminus yields error-free (non-slipped) TLS. The results indicate that there is a strong requirement for Rev7p during Pol zeta-mediated TLS measured in vivo. Furthermore, Rev1p is needed only for non-slipped TLS; slipped TLS remains efficient in its absence, revealing a previously uncharacterized Rev1p activity similar to Escherichia coli UmuDC function. Specifically, this activity is required for elongation from a correctly aligned lesion terminus.     

Distinct and cooperative roles for Nodal and Hedgehog signals during hypothalamic development

Despite its evolutionary conservation and functional importance, little is known of the signaling pathways that underlie development of the hypothalamus. Although mutations affecting Nodal and Hedgehog signaling disrupt hypothalamic development, the time and site of action and the exact roles of these pathways remain very poorly understood. Unexpectedly, we show here that cell-autonomous reception of Nodal signals is neither required for the migration of hypothalamic precursors within the neural plate, nor for further development of the anterior-dorsal hypothalamus. Nodal signaling is, however, cell-autonomously required for establishment of the posterior-ventral hypothalamus. Conversely, Hedgehog signaling antagonizes the development of posterior-ventral hypothalamus, while promoting anterior-dorsal hypothalamic fates. Besides their distinct roles in the regionalization of the diencephalon, we reveal cooperation between Nodal and Hedgehog pathways in the maintenance of the anterior-dorsal hypothalamus. Finally we show that it is the prechordal plate and not the head endoderm that provides the early signals essential for establishment of the hypothalamus.     

Distinct roles of PP1 and PP2A-like phosphatases in control of microtubule dynamics during mitosis.

Assembly of a mitotic spindle requires the accurate regulation of microtubule dynamics which is accomplished, at least in part, by phosphorylation-dephosphorylation reactions. Here we have investigated the role of serine-threonine phosphatases in the control of microtubule dynamics using specific inhibitors in Xenopus egg extracts. Type 2A phosphatases are required to maintain the short steady-state length of microtubules in mitosis by regulating the level of microtubule catastrophes, in part by controlling the the microtubule-destabilizing activity and phosphorylation of Op18/stathmin. Type 1 phosphatases are only required for control of microtubule dynamics during the transitions into and out of mitosis. Thus, although both type 2A and type 1 phosphatases are involved in the regulation of microtubule dynamics, they have distinct, non-overlapping roles.     

Distinct roles for JNK1 and JNK2 in regulating JNK activity and c-Jun-dependent cell proliferation

Different c-Jun N-terminal kinases (JNKs) are activated by a plethora of signals and phosphorylate substrates such as c-Jun, which is required for efficient cell cycle progression. Although JNK1 and JNK2 were shown to differentially regulate fibroblast proliferation, the underlying mechanistic basis remains unclear. We found that Jnk2-/- fibroblasts exit G1 and enter S phase earlier than wild-type counterparts, while Jnk1-/- cells show the inverse phenotype. Moreover, Jnk2-/- erythroblasts also exhibit a proliferative advantage. JNK2 deficiency results in elevated c-Jun phosphorylation and stability, whereas the absence of JNK1 reduces c-Jun phosphorylation and stability. Re-expression of JNK2 in Jnk2-/- cells reverses the JNK2 null phenotype, whereas ectopic expression of JNK1 augments it. JNK2 is preferentially bound to c-Jun in unstimulated cells, thereby contributing to c-Jun degradation. In contrast, JNK1 becomes the major c-Jun interacting kinase after cell stimulation. These data provide mechanistic insights into the distinct roles of different JNK isoforms.     

Distinct roles for antiparallel microtubule pairing and overlap during early spindle assembly

During spindle assembly, microtubules may attach to kinetochores or pair to form antiparallel pairs or interpolar microtubules, which span the two spindle poles and contribute to mitotic pole separation and chromosome segregation. Events in the specification of the interpolar microtubules are poorly understood. Using three-dimensional electron tomography and analysis of spindle dynamical behavior in living cells, we investigated the process of spindle assembly. Unexpectedly, we found that the phosphorylation state of an evolutionarily conserved Cdk1 site (S360) in γ-tubulin is correlated with the number and organization of interpolar microtubules. Mimicking S360 phosphorylation (S360D) results in bipolar spindles with a normal number of microtubules but lacking interpolar microtubules. Inhibiting S360 phosphorylation (S360A) results in spindles with interpolar microtubules and high-angle, antiparallel microtubule pairs. The latter are also detected in wild-type spindles <1 μm in length, suggesting that high-angle microtubule pairing represents an intermediate step in interpolar microtubule formation. Correlation of spindle architecture with dynamical behavior suggests that microtubule pairing is sufficient to separate the spindle poles, whereas interpolar microtubules maintain the velocity of pole displacement during early spindle assembly. Our findings suggest that the number of interpolar microtubules formed during spindle assembly is controlled in part through activities at the spindle poles.     

Distinct roles for Drosophila Dicer-1 and Dicer-2 in the siRNA/miRNA silencing pathways

The RNase III enzyme Dicer processes RNA into siRNAs and miRNAs, which direct a RNA-induced silencing complex (RISC) to cleave mRNA or block its translation (RNAi). We have characterized mutations in the Drosophila dicer-1 and dicer-2 genes. Mutation in dicer-1 blocks processing of miRNA precursors, whereas dicer-2 mutants are defective for processing siRNA precursors. It has been recently found that Drosophila Dicer-1 and Dicer-2 are also components of siRNA-dependent RISC (siRISC). We find that Dicer-1 and Dicer-2 are required for siRNA-directed mRNA cleavage, though the RNase III activity of Dicer-2 is not required. Dicer-1 and Dicer-2 facilitate distinct steps in the assembly of siRISC. However, Dicer-1 but not Dicer-2 is essential for miRISC-directed translation repression. Thus, siRISCs and miRISCs are different with respect to Dicers in Drosophila.