Complementary Roles of the Hippocampus and the Dorsomedial Striatum during Spatial and Sequence-Based Navigation Behavior

We investigated the neural bases of navigation based on spatial or sequential egocentric representation during the completion of the starmaze, a complex goal-directed navigation task. In this maze, mice had to swim along a path composed of three choice points to find a hidden platform. As reported previously, this task can be solved by using two hippocampal-dependent strategies encoded in parallel i) the allocentric strategy requiring encoding of the contextual information, and ii) the sequential egocentric strategy requiring temporal encoding of a sequence of successive body movements associated to specific choice points. Mice were trained during one day and tested the following day in a single probe trial to reveal which of the two strategies was spontaneously preferred by each animal. Imaging of the activity-dependent gene c-fos revealed that both strategies are supported by an overlapping network involving the dorsal hippocampus, the dorsomedial striatum (DMS) and the medial prefrontal cortex. A significant higher activation of the ventral CA1 subregion was observed when mice used the sequential egocentric strategy. To investigate the potential different roles of the dorsal hippocampus and the DMS in both types of navigation, we performed region-specific excitotoxic lesions of each of these two structures. Dorsal hippocampus lesioned mice were unable to optimally learn the sequence but improved their performances by developing a serial strategy instead. DMS lesioned mice were severely impaired, failing to learn the task. Our data support the view that the hippocampus organizes information into a spatio-temporal representation, which can then be used by the DMS to perform goal-directed navigation.     

Protein diffusion in crowded electrolyte solutions

We report on a combined cold neutron backscattering and spin-echo study of the short-range and long-range nanosecond diffusion of the model globular protein bovine serum albumin (BSA) in aqueous solution as a function of protein concentration and NaCl salt concentration. Complementary small angle X-ray scattering data are used to obtain information on the correlations of the proteins in solution. Particular emphasis is put on the effect of crowding, i.e. conditions under which the proteins cannot be considered as objects independent of each other. We thus address the question at which concentration this crowding starts to influence the static and in particular also the dynamical behaviour. We also briefly discuss qualitatively which charge effects, i.e. effects due to the interplay of charged molecules in an electrolyte solution, may be anticipated. Both the issue of crowding as well as that of charge effects are particularly relevant for proteins and their function under physiological conditions, where the protein volume fraction can be up to approximately 40% and salt ions are ubiquitous. The interpretation of the data is put in the context of existing studies on related systems and of existing theoretical models.     

Effect of cis-located human satellite DNA on the electroporation efficiency of neo and HSV-1 tk containing plasmids.

Highly repetitive satellite DNAs comprise a significant portion of higher eukaryotic genomes and have been implicated in a variety of chromosome processes, such as centromere structure and function, that are related to their presence in heterochromatin. In addition, heterochromatin can induce metastable expression of adjacent genes. However, the role of highly repetitive satellite DNAs in these effects remains to be elucidated. In an effort to address this question, plasmids containing a human 1797-bp EcoRI satellite II DNA, plus the neo and the HSV-1 tk genes, were electroporated into a TK-/NEO- human cell line. The presence of the satellite DNA sequences within the electroporated plasmids was found to interfere with the generation of stable TK+, but not NEO+, transfectants depending on the location and/or orientation of the cloned satellite DNA.     

Perinuclear cytoskeleton of acrosome-less spermatids in the blind sterile mutant mouse.

The perinuclear cytoskeleton of mammalian spermatids is thought to play a major role in nucleus-acrosome association and in shape changes of the head during spermiogenesis. To test these hypotheses acrosome-less spermatids in blind-sterile mutant mice were investigated for the development of the subacrosomal layer. Immunogold procedures were used for the detection of actin and calmodulin. In addition to various other abnormalities many acrosome-less round and elongating spermatids developed a subacrosomal layer with an actin and calmodulin distribution similar to that observed in normal spermatids. However, in mutant elongating spermatids the apical part of the nucleus was truncated and/or folded. The expected elongation and shaping of the nucleus only occurred in its caudal part associated with an hypertrophied and somewhat ectopic manchette. These abnormalities and those previously observed in mutant and experimental models indicated that the subacrosomal layer may form independently of the acrosome. It is suggested that the subacrosomal filamentous actin is a transitory scaffolding which might be involved in the assemblage of other proteins of the perinuclear cytoskeleton. However, by itself, this layer is not sufficient to ensure a normal shaping of the nucleus. Acrosome-nucleus interactions mediated by the subacrosomal layer seem necessary to shape the cranial spermatid head. The manchette appears to be involved only in the caudal nuclear shaping.     

The cytosolic chaperonin CCT associates to cytoplasmic microtubular structures during mammalian spermiogenesis and to heterochromatin in germline and somatic cells

Spermiogenesis, the haploid phase of spermatogenesis, is characterised by a dramatic cytodifferentiation of spermatids. The two major steps, nuclear shaping and cytoplasmic reorganisation of the organelles, rely on an extensive remodelling of the microtubule cytoskeleton. Folding of alpha- and beta-tubulin is mediated by the cytoplasmic chaperonin containing TCP-1 (CCT), highly expressed in testis. We studied CCT cellular distribution throughout spermatogenesis by immunofluorescence and immunoelectron microscopy. We unveil two main cytoplasmic localisations for CCT: at the centrosome and at the microtubules of the manchette, a structure unique to male germ cells. Both structures are essential for spermatid differentiation and may require CCT function. Although CCT is essentially cytoplasmic, a few reports suggest that a subset may have a nuclear localisation. We demonstrate that in the nucleus of germline and somatic cells, part of CCT associates to heterochromatin. In interphase cells, CCT seems generally confined to constitutive heterochromatin. Nevertheless, in condensing nucleus of future spermatozoon, it is also associated with chromatin undergoing compaction. Finally, in fully-condensed mitotic chromosomes, CCT is located all along the chromosomes. Our finding that CCT is associated with constitutive heterochromatin and to compacting chromatin raises the possibility that it may be implicated in maintenance and remodelling of heterochromatin.     

Improving Axial Resolution in Confocal Microscopy with New High Refractive Index Mounting Media

Resolution, high signal intensity and elevated signal to noise ratio (SNR) are key issues for biologists who aim at studying the localisation of biological structures at the cellular and subcellular levels using confocal microscopy. The resolution required to separate sub-cellular biological structures is often near to the resolving power of the microscope. When optimally used, confocal microscopes may reach resolutions of 180 nm laterally and 500 nm axially, however, axial resolution in depth is often impaired by spherical aberration that may occur due to refractive index mismatches. Spherical aberration results in broadening of the point-spread function (PSF), a decrease in peak signal intensity when imaging in depth and a focal shift that leads to the distortion of the image along the z-axis and thus in a scaling error. In this study, we use the novel mounting medium CFM3 (Citifluor Ltd., UK) with a refractive index of 1.518 to minimize the effects of spherical aberration. This mounting medium is compatible with most common fluorochromes and fluorescent proteins. We compare its performance with established mounting media, harbouring refractive indices below 1.500, by estimating lateral and axial resolution with sub-resolution fluorescent beads. We show furthermore that the use of the high refractive index media renders the tissue transparent and improves considerably the axial resolution and imaging depth in immuno-labelled or fluorescent protein labelled fixed mouse brain tissue. We thus propose to use those novel high refractive index mounting media, whenever optimal axial resolution is required.