The effect of peer contact upon physiological response to maternal separation

The response of both human and nonhuman primate infants to separation from their mothers is characterized by agitation or protest behaviors followed by a behavioral depressive reaction. In monkeys, this behavioral syndrome has striking physiological correlates, including heart rate and sleep disturbances. There is, however, considerable individual variability in response to maternal separation. The authors hypothesized that the amount of contact with particular, familiar conspecifics might account for some of this variability. In support of this notion, data are presented that indicate that pigtailed monkey infants who have been separated from their mothers but who maintain relatively high levels of peer contact do not show as severe decreases in heart rate during maternal separation as do those that exhibit less peer contact.     

A simple approach for mouse embryonic stem cells isolation and differentiation inducing embryoid body formation

Stem cells were derived from hatched blastocyst-stage mouse embryos of the C57BL/6 strain employing a knockout serum replacement instead of the traditional fetal calf serum, thereby avoiding the use of immunosurgery. Although fetal calf serum was not good for isolation of stem cells, a combination of this serum plus knockout serum increased the expansion rate of the cell culture. The derived cells were capable of maintaining an undifferentiated state during several passages, as demonstrated by the presence of alkaline phosphatase activity, stage-specific embryonic antigen 1 (SSEA-1), and octamer binding protein 4 (Oct-4). Suspension culture in bacteriological dishes gave better results than the hanging drop method for differentiation by means of embryoid body formation. Mouse embryonic stem cells showed spontaneous differentiation into derivatives of the 3 germ layers in culture media supplemented with fetal calf serum but not with knockout serum.     

Growth behavior of number distributed adherent MDCK cells for optimization in microcarrier cultures

An assay for measuring the number of adherent cells on microcarriers that is independent from dilution errors in sample preparation was used to investigate attachment dynamics and cell growth. It could be shown that the recovery of seeded cells is a function of the specific rates of cell attachment and cell death, and finally a function of the initial cell‐to‐bead ratio. An unstructured, segregated population balance model was developed that considers individual classes of microcarriers covered by 1–220 cells/bead. The model describes the distribution of initially attached cells and their growth in a microcarrier system. The model distinguishes between subpopulations of dividing and nondividing cells and describes in a detailed way cell attachment, cell growth, density‐dependent growth inhibition, and basic metabolism of Madin‐Darby canine kidney cells used in influenza vaccine manufacturing. To obtain a model approach that is suitable for process control applications, a reduced growth model without cell subpopulations, but with a formulation of the specific cell growth rate as a function of the initial cell distribution on microcarriers after seeding was developed. With both model approaches, the fraction of growth‐inhibited cells could be predicted. Simulation results of two cultivations with a different number of initially seeded cells showed that the growth kinetics of adherent cells at the given cultivation conditions is mainly determined by the range of disparity in the initial distribution of cells on microcarriers after attachment. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Three-dimensional temporomandibular joint muscle attachment morphometry and its impacts on musculoskeletal modeling

In musculoskeletal models of the human temporomandibular joint (TMJ), muscles are typically represented by force vectors that connect approximate muscle origin and insertion centroids (centroid-to-centroid force vectors). This simplification assumes equivalent moment arms and muscle lengths for all fibers within a muscle even with complex geometry and may result in inaccurate estimations of muscle force and joint loading. The objectives of this study were to quantify the three-dimensional (3D) human TMJ muscle attachment morphometry and examine its impact on TMJ mechanics. 3D muscle attachment surfaces of temporalis, masseter, lateral pterygoid, and medial pterygoid muscles of human cadaveric heads were generated by co-registering measured attachment boundaries with underlying skull models created from cone-beam computerized tomography (CBCT) images. A bounding box technique was used to quantify 3D muscle attachment size, shape, location, and orientation. Musculoskeletal models of the mandible were then developed and validated to assess the impact of 3D muscle attachment morphometry on joint loading during jaw maximal open-close. The 3D morphometry revealed that muscle lengths and moment arms of temporalis and masseter muscles varied substantially among muscle fibers. The values calculated from the centroid-to-centroid model were significantly different from those calculated using the ‘Distributed model’, which considered crucial 3D muscle attachment morphometry. Consequently, joint loading was underestimated by more than 50% in the centroid-to-centroid model. Therefore, it is necessary to consider 3D muscle attachment morphometry, especially for muscles with broad attachments, in TMJ musculoskeletal models to precisely quantify the joint mechanical environment critical for understanding TMJ function and mechanobiology.     

The functional significance of density and distribution of outgrowths on co-opted contact pairs in biological arresting systems

Microstructures responsible for temporary arresting of contacting surfaces are widely distributed on surfaces in different organisms. Recent morphological studies show that these structures have different density of outgrowths and not ideal distribution pattern on both complementary parts of the contact. One can suggest that this difference is optimized by natural selection to get stronger mechanical arrest within the system. In this paper, we simulate such a system numerically, both in the frames of continuous contact and discrete dynamical models to prove this hypothesis and elucidate other aspects of optimization of such mechanical adhesive systems.     

Cell antigens recognized by rabbit antibodies specific for oligomannosyl determinants

Rabbit antibodies to cell wall mannans of various microbial strains and their mutants were found to be cross-reactive to cell carbohydrates of mammalian sperm and 4–6-day-old blastocysts. Immunochemical studies indicate that oligomers of α1→2, α1→3, α1→6, and probably also α→4 linked mannose residues of sperm carbohydrates are available for antibody binding. At least 80% of binding activity of a yeast mannan antibody to sperm can be effectively inhibited by specific haptens or digestion with exo-α-D-mannosidase, an enzyme activity highest in testicular tissue. In order to determine the role of this enzyme in the metabolism of the cross-reactive mannan antigens of sperm, the relative amount of a specific α-linked oligomannosyl determinant of bovine sperm from homozygous normals was compared to that of heterozygous carriers of α-mannosidase deficiency. Extensive cross-reactivity between the microbial and mammalian oligomannosyl determinants suggest that these are conserved structures in cell carbohydrates, although the organization of these units in the microbial cell wall lipopolysaccharide has very little similarity to the carbohydrate moieties of mammalian glycoproteins.     

Role of Autophagy Pathway in Parkinson’s Disease and Related Genetic Neurological Disorders

The elucidation of the function of the PINK1 protein kinase and Parkin ubiquitin E3 ligase in the elimination of damaged mitochondria by autophagy (mitophagy) has provided unprecedented understanding of the mechanistic pathways underlying Parkinson’s disease (PD). We provide a comprehensive overview of the general importance of autophagy in Parkinson’s disease and related disorders of the central nervous system. This reveals a critical link between autophagy and neurodegenerative and neurodevelopmental disorders and suggests that strategies to modulate mitophagy may have greater relevance in the CNS beyond PD.     

The C2B Domain Is the Primary Ca Sensor in DOC2B: A Structural and Functional Analysis

DOC2B (double-C₂ domain) protein is thought to be a high-affinity Ca^2 + sensor for spontaneous and asynchronous neurotransmitter release. To elucidate the molecular features underlying its physiological role, we determined the crystal structures of its isolated C2A and C2B domains and examined their Ca^2 +-binding properties. We further characterized the solution structure of the tandem domains (C2AB) using small-angle X-ray scattering. In parallel, we tested structure–function correlates with live cell imaging tools. We found that, despite striking structural similarity, C2B binds Ca^2 + with considerably higher affinity than C2A. The C2AB solution structure is best modeled as two domains with a highly flexible orientation and no difference in the presence or absence of Ca^2 +. In addition, kinetic studies of C2AB demonstrate that, in the presence of unilamellar vesicles, Ca^2 + binding is stabilized, as reflected by the ~ 10-fold slower rate of Ca^2 + dissociation than in the absence of vesicles. In cells, isolated C2B translocates to the plasma membrane (PM) with an EC₅₀ of 400 nM while the C2A does not translocate at submicromolar Ca^2 + concentrations, supporting the biochemical observations. Nevertheless, C2AB translocates to the PM with an ~ 2-fold lower EC₅₀ and to a greater extent than C2B. Our results, together with previous studies, reveal that the C2B is the primary Ca^2 + sensing unit in DOC2B, whereas C2A enhances the interaction of C2AB with the PM.