Divergent expression of alpha1-protease inhibitor genes in mouse and human

The alpha1-protease inhibitor proteins of laboratory mice are homologous in sequence and function to human alpha1-antitrypsin and are encoded by a highly conserved multigene family comprised of five members. In humans, the inhibitor is expressed in liver and in macrophages and decreased expression or inhibitory activity is associated with a deficiency syndrome which can result in emphysema and liver disease in affected individuals. It has been proposed that macrophage expression may be an important component of the function of human alpha1-antitrypsin. Clearly, it is desirable to develop a mouse model of this deficiency syndrome, however, efforts to do this have been largely unsuccessful. In this paper, we report that aside from the issues of potentially redundant gene function, the mouse may not be a suitable animal for such studies, because there is no significant expression of murine alpha1-protease inhibitor in the macrophages of mice. This difference between the species appears to result from an absence of a functional macrophage-specific promoter in mice.     

Pressure diuresis and natriuresis in DOCA-salt mice

The increasing use of mice in renal and cardiovascular studies has necessitated adapting physiological methods used for rats to mice, which are far smaller in size. We have adapted measurements of continuous renal blood flow, pressure natriuresis and diuresis, and laser-Doppler cortical and medullary flow to 40 g mice with DOCA-salt hypertension. We demonstrated a rightward shift in the pressure-natriuresis-diuresis curve. We conclude that with current, commercially-available equipment, sophisticated renal physiology can be conducted in the mouse. These methods will be important to investigations of gene-targeted mice.     

Fear conditioning in inbred mouse strains: An analysis of the time course of memory.

Three mouse strains were examined for short- and long-term memory for Pavlovian fear conditioning measured 1 hr and 24 hr after conditioning. Both DBA/2J and CBA/J mice exhibit reduced long-term memory for contextual fear conditioning compared with C57BL/6J mice. In cued fear conditioning, however, DBA/2J mice show reduced short- and long-term memory compared with C57BL/6J mice, whereas CBA/J mice exhibit reductions only in short-term memory. These results underscore the importance of examining the time course of memory retention, and they suggest that inbred mouse strains may provide a diversity of phenotypes. The results also suggest that the processes of short- and long-term memory storage as well as contextual and cued fear conditioning are dissociable and are mediated by genetically distinct neurobiological mechanisms. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

B cells are anergic in transgenic mice that express IgM anti-DNA antibodies

B lymphocytes in individuals with systemic lupus erythematosus (SLE) secrete pathogenic autoantibodies to DNA which cause clinical nephritis. (NZB X NZW) F1 (BW) female mice also secrete pathogenic anti-DNA autoantibodies, and therefore are considered to be an animal model of SLE. The rearranged immunoglobulin (Ig) genes that encode an anti-DNA antibody from a diseased BW mouse have been cloned, and transgenic (Tg) mice have been created by microinjection of these constructs into fertilized eggs from normal mice. As we reported previously, when the construct contains the C gamma 2a heavy chain constant (CH) region, the mice spontaneously secrete anti-DNA IgG and they develop mild nephritis. This demonstrated that the Ig encoded by the transgene is pathogenic. In contrast, here we report that when the construct contains the same anti-DNA Ig variable (V) regions used previously, along with the C mu region, the autoreactive B cells are rendered tolerant. Most B cells in the Tg mice express the mu transgene product on their surface, and rearrangement of endogenous light chain genes is partially suppressed. Furthermore, most hybridomas made from Tg B cells secrete IgM anti-DNA. Despite this, the Tg mice have reduced levels of total serum Ig and they do not secrete anti-DNA IgM either spontaneously or following immunization with DNA. We conclude that most B cells in the Tg mice have been rendered anergic. Anergy is however reversible in vitro; lipopolysaccharide stimulation of Tg B cells leads to the production of a significant amount of IgM anti-DNA antibody. The studies demonstrate that in this line of Tg mice on a normal mouse genetic background potentially pathogenic B cells that express a high-affinity Ig specific for a natural autoantigen are subject to tolerance by induction of anergy.     

Behavioural performance in three substrains of mouse strain 129

Recently, the possibility has been raised that the behavioural abnormalities seen in null-mutant mice might be determined by their genetic background rather than by loss of gene function, especially when the 129 mouse strain is used as supplier for embryonic stem (ES) cells. To examine this issue we tested three 129 mouse substrains (129/J, 129/Ola, 129/Sv-ter/+) and C57BL/6 (B6) in the Morris water maze, the open field, the plus maze and two tests assessing motor co-ordination. We identified only for the 129/J substrain substantial behavioural deficits. These mice are albinos and carry the pink-eyed dilution allele and differed in their basal anxiety level as assessed in the open-field test. They were severely impaired in spatial learning and memory (Morris water maze test), in the Porsolt swim test, which also measures learning and in motor co-ordination. However, the 129/J substrain has not been used as ES cell donor in null-mutant mice where behavioural abnormalities were observed. Instead, mice from 129/Ola and 129/Sv-ter/+ substrains have been commonly used as suppliers for ES cells. These performed normally in most of the tests, including Morris water maze test.     

Cellular learning theory: Theoretical comment on Cole and McNally (2007).

The idea that learning proceeds as a function of the discrepancy (or error) between expected and obtained outcomes is central to many theories of associative learning. However, remarkably little is known about the neurobiological mechanisms that underlie this learning of predictive errors in fear conditioning, a widely used preparation in studies of cellular and molecular mechanisms of memory. In this issue of Behavioral Neuroscience, S. Cole and G. P. McNally (see record 2007-13974-022) demonstrate an important dissociation between the establishment and regulation of predictive error at the cellular level. Their findings have added a level of complexity to currently established views of the function of NMDA and opioid receptors in learning and memory. This commentary discusses some of the implications of these findings for theoretical and neurobiological approaches to memory, as well as current thinking about the cellular circuitry involved in reward learning and drug abuse. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Modification of gene activity in mouse embryos in utero by a tamoxifen-inducible form of Cre recombinase

The ability to generate specific genetic modifications in mice provides a powerful approach to assess gene function. When genetic modifications have been generated in the germ line, however, the resulting phenotype often only reflects the first time a gene has an influence on - or is necessary for - a particular biological process. Therefore, systems allowing conditional genetic modification have been developed (for a review, see [1]); for example, inducible forms of the Cre recombinase from P1 phage have been generated that can catalyse intramolecular recombination between target recognition sequences (loxP sites) in response to ligand [2] [3] [4] [5]. Here, we assessed whether a tamoxifen-inducible form of Cre recombinase (Cre-ERTM) could be used to modify gene activity in the mouse embryo in utero. Using the enhancer of the Wnt1 gene to restrict the expression of Cre-ERTM to the embryonic neural tube, we found that a single injection of tamoxifen into pregnant mice induced Cre-mediated recombination within the embryonic central nervous system, thereby activating expression of a reporter gene. Induction was ligand dependent, rapid and efficient. The results demonstrate that tamoxifen-inducible recombination can be used to effectively modify gene function in the mouse embryo.     

Reduction in amyloid A amyloid formation in apolipoprotein-E-deficient mice

Apolipoproteins have been implicated in the formation of amyloid fibrils. Recent studies have demonstrated that apolipoprotein E (apoE), alone or in combination with apolipoprotein J (apoJ), and other lipoproteins appear to enhance deposition of amyloid fibrils both in systemic and cerebral amyloids, especially Alzheimer's disease (AD). ApoE enhanced the ability of the amyloid beta-protein (1-40) fragment (A beta) to form fibrils in vitro, with apoE4 promoting the greatest fibril formation. ApoE was found associated with both human and mouse amyloid A (AA) deposits. To define the role of apoE in vivo, we utilized mice lacking the apoE gene by gene targeting. We used the AA model in mice to characterize the function of the apoE protein in amyloid fibrillogenesis. ApoE-deficient mice exhibited a decrease in deposition of AA when compared with heterozygous mutant or wild-type animals. In addition, apoE-deficient mice that were injected with an adenovirus that expressed the human apoE3 gene had restored AA deposition and the apoE was associated with the AA fibrils. These results are agreement with the in vitro studies using the beta-peptide and suggest that apoE is not essential for amyloid fibrillogenesis but can promote the development of amyloid deposition.     

Oral contraceptives and bone metabolism

Erythropoietin (EPO) is a glycoprotein which appears as the primary regulator of erythropoiesis under either normal or most of the pathologic conditions. In the rat with experimentally-reduced erythropoiesis, daily administration of 1.3 IRP units can restore the function and maintain steady-state conditions of red cell formation. This important information for the programming of both physiologic and pharmacologic studies is lacking for the mouse, in spite of the fact that most of the experiments performed on the regulation of erythropoiesis have been conducted in this species. In the present study, designed to determine EPO requirement for maintenance of steady-state erythropoiesis in the adult mouse under standard laboratory conditions, adult females of the CF#1 strain were exposed to hypobaria (18 h/day) during a 3-week period for induction of polycythemia (P). At the end of the hypoxic period. P mice were maintained at sea level conditions, as were normocythemic (N) mice during the entire experimental period. P mice were daily injected with 0, 0.5, 1.0, 1.5, or 2.0 IRP units of rHu-EPO during the 4-day period that followed the hypoxic one. The rate of erythropoiesis in N and P mice were measured by RBC-59Fe uptake. The plasma 59Fe half-clearance time was also measured in other groups of N and P mice similarly treated. One-way ANOVA showed that the only non-significant difference (P > 0.05) between N and EPO-injected P mice was established for the 1.0 unit dose group. It is thus suggested that approximately 1.0 unit of EPO should be synthesized daily in an adult mice to maintain a normal rate of erythropoiesis.     

Progressive pancreatic islet hyperplasia in the islet-targeted, parathyroid hormone-related protein-overexpressing mouse

PTH-related protein (PTHrP) is a paracrine/autocrine factor produced in most cell types in the body. Its functions include the regulation of cell cycle, of differentiation, of apoptosis, and of developmental events. One of the cells which produces PTHrP is the pancreatic beta cell. We have previously described a transgenic mouse model of targeted overexpression of PTHrP in the beta cell, the RIP-PTHrP mouse. These studies showed that PTHrP overexpression markedly increased islet mass and insulin secretion and resulted in hypoglycemia. Those studies were limited to RIP-PTHrP mice of 8-12 weeks of age. In the current report, we demonstrate that PTHrP overexpression induces a progressive increase in islet mass over the life of the RIP-PTHrP mouse, and that, in contrast to some other models of targeted PTHrP overexpression, the phenotype is not developmental, but occurs postnatally. The marked increase in islet mass is not associated with a measurable increase in beta cell replication rates. A further slowing in the normally low islet apoptosis rate could not be demonstrated in the RIP-PTHrP islet. Thus, the marked increase in islet mass in the RIP-PTHrP mouse is unexplained in mechanistic terms. Finally, RIP-PTHrP mice are resistant to the diabetogenic effects of streptozotocin. The mechanisms responsible for the increase in islet mass in the RIP-PTHrP mouse likely lie in either very subtle changes in islet turnover or in early steps in islet differentiation and development. The ability of PTHrP to increase islet mass and function, as well as its ability to attenuate the diabetogenic effects of streptozotocin, indicate that further study of PTHrP on islet development and function are important and may lead to therapeutic strategies in diabetes mellitus.     

Using genetically modified mice to study apolipoprotein B

The B apolipoproteins, apo-B48 and apo-B100, are key proteins in mammalian lipoprotein metabolism and are components of all classes of lipoproteins considered to be atherogenic. Our laboratory has generated an array of genetically modified mice for studying apo-B biology. Using gene targeting in mouse embryonic stem cells, we have generated apo-B-deficient mice. Heterozygotes had low plasma levels of apo-B and cholesterol; homozygotes died early in embryonic development, most likely because the absence of lipoprotein secretion by the yolk sac interfered with the delivery of lipid nutrients to the developing embryo. We have also generated human apo-B transgenic mice with an 80-kb genomic DNA fragment spanning the entire human apo-B gene; those mice had markedly increased plasma levels of low density lipoprotein cholesterol and exhibited increased susceptibility to atherosclerosis. The human apo-B transgenic mice have also yielded insights regarding the regulation of apo-B expression in different tissues. Although the 80-kb transgene contained nearly 20 kb of 5' and 3' flanking sequences and was expressed at high levels in the liver, no transgene expression was detectable in the intestine. Subsequent transgenic mouse studies have demonstrated that the expression of the apo-B gene in the intestine is controlled by DNA sequences that are very distant from the structural gene. Transgenic mice have also proved useful for studying apo-B structure/function relationships. By expressing mutant forms of human apo B in transgenic mice, we have examined the structural features of the apo-B molecule that are required for lipoprotein (a) formation. We have demonstrated that the carboxyl terminal cystine residue of apo-B100, cysteine-4326, is required for apo-B100's disulfide linkage with apo(a) to form lipoprotein (a). Finally, we have used gene targeting techniques to generate mice that synthesize exclusively apo-B48 (apo B48-only mice) and mice that synthesize exclusively apo-B100 (apo-B100 only mice): These mice have helped to clarify the unique metabolic roles of the two apo-B proteins.     

Transgenic mouse models of lipoprotein metabolism and atherosclerosis

Lipoprotein transport genes have either been added to the germ line of mice by transgenic techniques or knocked out by homologous recombination in embryonic stem cells. The resultant over- or underexpression of these genes has resulted in new insights about how these genes function in the body and their role in lipoprotein metabolism. Either singly or in combination, these genetic modifications can be used to engineer the mouse to make it a better model for human lipoprotein disorders and atherosclerosis.     

Adjuvant therapy for stage I testicular cancer

A variety of possible mechanisms for the loss of CD4+ T cells has been proposed, such as direct cytopathic effects by HIV-1 infection, and indirect induction of apoptosis. However, the fundamental picture of major and central pathogenic processes for the decay of immune systems is still missing in understanding the pathogenic mechanisms of HIV-1 infected humans. It is more appropriate to expand our focus onto entire organ systems involved in the development of immune system such as bone marrow and thymus. From the observations in the clinical studies, HIV-1 causes a variety of pathology on the T cell development pathway even from the hematopoietic progenitors and immature thymocytes, which should have a substantial impact on the failure of T cell homeostasis in the periphery. The SCID-hu mouse constructed by surgical implantation of human fetal hemato-lymphoid organs into the immunodeficient mouse has been used for the experimental evaluation of various parameters associated with HIV-1 infection and hematosuppression. Given the apparently normal structure and function of the human implants, the SCID-hu bone and Thy/Liv mice would appear to be potentially reliable models for the analysis of human physiology and patho-physiology.     

Incomplete rescue of cystic fibrosis transmembrane conductance regulator deficient mice by the human CFTR cDNA

We have used a mouse model to study the ability of human CFTR to correct the defect in mice deficient of the endogenous protein. In this model, expression of the endogenous Cftr gene was disrupted and replaced with a human CFTR cDNA by a gene targeted 'knock-in' event. Animals homozygous for the gene replacement failed to show neither improved intestinal pathology nor survival when compared to mice completely lacking CFTR. RNA analyses showed that the human CFTR sequence was transcribed from the targeted allele in the respiratory and intestinal epithelial cells. Furthermore, in vivo potential difference measurements showed that basal CFTR chloride channel activity was present in the apical membranes of both nasal and rectal epithelial cells in all homozygous knock-in animals examined. Ussing chamber studies showed, however, that the cAMP-mediated chloride channel function was impaired in the intestinal tract among the majority of homozygous knock-in animals. Hence, failure to correct the intestinal pathology associated with loss of endogenous CFTR was related to inefficient functional expression of the human protein in mice. These results emphasize the need to understand the tissue-specific expression and regulation of CFTR function when animal models are used in gene therapy studies.     

Strategic processing and episodic memory impairment in obsessive compulsive disorder.

There is evidence that nonverbal memory problems in obsessive compulsive disorder (OCD) are mediated by impaired strategic processing. Although many studies have found verbal memory to be normal in OCD, these studies did not use tests designed to stress organizational strategies. This study examined verbal and nonverbal memory performance in 33 OCD patients and 30 normal control participants with the Rey-Osterrieth Complex Figure Test and the California Verbal Learning Test. OCD patients were impaired on verbal and nonverbal measures of organizational strategy and free recall. Multiple regression modeling indicated that free recall problems in OCD were mediated by impaired organizational strategies used during learning trials. Therefore, verbal and nonverbal episodic memory deficits in OCD are affected by impaired strategic processing. Results are consistent with neurobiological models proposing frontal-striatal system dysfunction in OCD. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Scrambler and yotari disrupt the disabled gene and produce a reeler-like phenotype in mice

Formation of the mammalian brain requires choreographed migration of neurons to generate highly ordered laminar structures such as those in the cortices of the forebrain and the cerebellum. These processes are severely disrupted by mutations in reelin which cause widespread misplacement of neurons and associated ataxia in reeler mice. Reelin is a large extracellular protein secreted by pioneer neurons that coordinates cell positioning during neurodevelopment. Two new autosomal recessive mouse mutations, scramble and yotari have been described that exhibit a phenotype identical to reeler. Here we report that scrambler and yotari arise from mutations in mdab1, a mouse gene related to the Drosophila gene disabled (dab). Both scrambler and yotari mice express mutated forms of mdab1 messenger RNA and little or no mDab1 protein. mDab1 is a phosphoprotein that appears to function as an intracellular adaptor in protein kinase pathways. Expression analysis indicates that mdab1 is expressed in neuronal populations exposed to Reelin. The similar phenotypes of reeler, scrambler, yotari and mdab1 null mice indicate that Reelin and mDab1 function as signalling molecules that regulate cell positioning in the developing brain.     

Molecular and functional aspects of the hairless (hr) gene in laboratory rodents and humans

For many years, hairless and rhino mouse mutants have provided a useful and extensively exploited model for studying different aspects of skin physiology, including skin aging, pharmacokinetic evaluation of drug activity and cutaneous absorption, skin carcinogenesis, and skin toxicology. Interestingly, however, hairless and rhino mice have rarely been studied for their primary cellular defect - hairlessness - and thus, the hairless gene itself and its physiological functions have been largely overlooked for decades. The recent identification of the human homolog of the hairless gene on human Chromosome 8p12 confirmed the clinical significance of the phenomenon of "hairlessness" in humans, which was predicted on the basis of similarities between hairless mice and a congenital hair disorder characterized by atrichia with papules. Mutations in the hairless gene of mice provide instructive models for further studies of hr gene function, and may facilitate insights into the pathophysiology of different human disorders associated with the disruption of hr gene activity. We provide an overview of current data on the structure and expression patterns of the hr gene, and of mutations at the hairless locus in mice and humans, including the genetic basis of different alleles, the pathology of hairlessness, reproductive and immunological defects, and susceptibility to dioxin toxicity. On the basis of our current understanding of hairlessness, we speculate on the putative functions of the hr gene product in skin physiology, and particularly, in hair follicle biology.     

A review of vasomotor responses of arterioles on the surface of the mouse brain: the necessary prelude to studies using genetically manipulated mice

OBJECTIVE: To review the published data concerning the vasomotor responses of arterioles on the surface of the mouse brain. This information is essential to the planning of studies using genetically manipulated mice to investigate the control of cerebral vascular resistance. RESULTS: Cerebral vasomotor responses of mice have been reported using a wide variety of vasoactive agents. The responses are usually like those of other laboratory animals. Some agents are capable of eliciting opposing dilating and constricting responses. The initial tone of the arteriole is one of several factors that can determine the direction of the response elicited by such agents. Endothelium-dependent dilators and constrictors have been described. There are a variety of endothelium-derived relaxing factors (EDRFs). Only one of these is synthesized by nitric oxide synthase (NOS). Antisense data suggests that both the endothelial and the neuronal isoforms of NOS may exist in the endothelial cells of these vessels. Several diseases can be modeled in mice and cerebrovascular responses studied. Studies of genetically modified mice suggest that the endothelial form of NOS contributes to microvascular events, which limit ischemic damage to brain parenchyma. However, during and following ischemia there may be loss of this NOS or inability to mobilize a storage form of the EDRF, which it produces. CONCLUSIONS: Data available from studies of mice provide a good basis for planning further studies, examining cerebrovascular control mechanisms in health and disease, by workers now using genetically modified mice. The latter represent a powerful and increasingly popular tool for this purpose.     

Multi-modality mapping of motor cortex: comparing echoplanar BOLD fMRI and transcranial magnetic stimulation. Short communication

Multiple non-invasive methods of imaging brain function are now available for presurgical planning and neurobiological research. As these new methods become available, it is important to understand their relative advantages and liabilities, as well as how the information gained compares across different methods. A current and future trend in neurobiological studies as well as presurgical planning is to combine information from different imaging techniques. Multi-modal integration may perhaps give more powerful information than each modality alone, especially when one of the methods is transcranial magnetic stimulation (TMS), with its ability to non-invasively activate the brain. As an initial venture in cross comparing new imaging methods, we performed the following 2 studies, locating motor cortex with echoplanar BOLD fMRI and TMS. The two methods can be readily integrated, with concurring results, although each have important limitations.     

SPECT and PET in neurobiology

PET (positron emission tomography) and SPECT (single photon emission computed tomography) are isotopic methods in which the distribution is registered of radiolabelled tracers given in such small amounts that they are without effect on the organism or the organism's disposal of them. Thus, a series of important biological processes in the intact organism can be studied. The methods have been used in many disciplines but in particular for neurobiological research on the brain--e.g., the brain's regional blood circulation and mapping of the brain's functional structure. The methods have also been used in the investigation of glucose and amino acid metabolism in the brain and receptor conditions.