Ruthless reductionism and social cognition

Social cognition appears to present phenomena that "ruthlessly reductive" molecular and cellular neuroscience cannot fruitfully investigate or explain. This is because the causes of such phenomena are distal and external not only to the molecular machinery of individual neurons, but to individual brains. However, the "reductionist's epiphany" insists that to the extent that we understand the specific molecular mechanisms that underlie phenomena upon which most or all social cognition depends, we can be sure that molecular mechanisms for the broader phenomena can be found using standard experimental methods from molecular and cellular cognition. Furthermore, social recognition memory consolidation is required for virtually all types of social cognition, and its specific molecular mechanisms have now been uncovered experimentally. These same molecular mechanisms obtain across a wide variety of divergent species (from invertebrates to vertebrates). Thus we can expect to find the molecular mechanisms of the broader social cognitive functions that must "plug into" these specific molecular mechanisms, despite these functions' typically distal, external initial causes. This conclusion rests on explicit scientific facts, not just on some vague philosophical commitment to physicalism about mind.     

Modulating Molecular Functions of p53 with Small Molecules

Association of the p53 with many human cancers makes it a valuable therapeutic target. Stress-induced molecular interactions of p53 with other effector proteins are immensely intertwined with regulation of its functions in orchestrating a wide array of cellular responses, thereby defying analysis of the underlying molecular mechanisms with conventional molecular and cellular biology methods. Recent discoveries of small molecules that can selectively modulate the molecular interactions of p53 offer promising opportunities to address the challenge of dissecting these complex mechanisms and increase the hope for pharmacological control of p53 for clinical benefits of cancer patients.     

Molecular mechanisms of phosphate transport in plants

Membrane-spanning transport proteins are responsible for the selective passage of most mineral nutrients and metabolites across cellular and intracellular membranes. This review's focus is on summarising the current state of research covering the molecular regulation and biochemical mechanisms involved in the transport of phosphorus, an often growth-limiting nutrient, in vascular plants. Physiological data illustrating the tight control of Pi homeostasis on the cellular as well as on the organism's level are discussed together with the recent results on molecular transport mechanisms.     

New circuits for old memories: the role of the neocortex in consolidation

Studies of learning and memory have provided a great deal of evidence implicating hippocampal mechanisms in the initial storage of facts and events. However, until recently, there were few hints as to how and where this information was permanently stored. A recent series of rodent molecular and cellular cognition studies provide compelling evidence for the involvement of specific neocortical regions in the storage of information initially processed in the hippocampus. Areas of the prefrontal cortex, including the anterior cingulate and prelimbic cortices, and the temporal cortex show robust increases in activity specifically following remote memory retrieval. Importantly, damage to or inactivation of these areas produces selective remote memory deficits. Additionally, transgenic studies provide glimpses into the molecular and cellular mechanisms underlying cortical memory consolidation. The studies reviewed here represent the first exciting steps toward the understanding of the molecular, cellular, and systems mechanisms of how the brain stores our oldest and perhaps most defining memories.     

Post-transcriptional gene silencing in neurons

The techniques evolving from the rapidly developing field of small RNAs promise accessible approaches to dissecting cellular and molecular mechanisms of higher brain function. Here, a current overview of the technology is presented, along with an outline of how these approaches might help neuroscientists to more rapidly uncover the cellular and molecular bases of behavior.     

How to eat something bigger than your head

Characterization of the mechanisms underlying various types of muscular dystrophy has been an outstanding triumph of molecular biology. Increasing clarification of the aberrant cellular processes responsible for these conditions may ultimately permit the development of effective means for molecular intervention, allowing correction of the abnormal cellular physiology that results in the dystrophic phenotype.     

Pathological axes of wound repair: Gastrulation revisited

Post-traumatic inflammation is formed by molecular and cellular complex mechanisms whose final goal seems to be injured tissue regeneration. In the skin -an exterior organ of the body- mechanical or thermal injury induces the expression of different inflammatory phenotypes that resemble similar phenotypes expressed during embryo development. Particularly, molecular and cellular mechanisms involved in gastrulation return. This is a developmental phase that delineates the three embryonic germ layers: ectoderm, endoderm and mesoderm. Consequently, in the post-natal wounded skin, primitive functions related with the embryonic mesoderm, i.e. amniotic and yolk sac-derived, are expressed. Neurogenesis and hematogenesis stand out among the primitive function mechanisms involved. Interestingly, in these phases of the inflammatory response, whose molecular and cellular mechanisms are considered as traces of the early phases of the embryonic development, the mast cell, a cell that is supposedly inflammatory, plays a key role. The correlation that can be established between the embryonic and the inflammatory events suggests that the results obtained from the research regarding both great fields of knowledge must be interchangeable to obtain the maximum advantage.     

The dynamics of cellular injury: transformation into neuronal and vascular protection

Despite the immediate event, such as cerebral trauma, cardiac arrest, or stroke that may result in neuronal or vascular injury, specific cellular signal transduction pathways in the central nervous system ultimately influence the extent of cellular injury. Yet, it is a cascade of mechanisms, rather than a single cellular pathway, which determine cellular survival during toxic insults. Although neuronal injury associated with several disease entities, such as Alzheimer's disease, Parkinson's disease, and cerebrovascular disease was initially believed to be irreversible, it has become increasingly evident that either acute or chronic modulation of the cellular and molecular environment within the brain can prevent or even reverse cellular injury. In order to develop rational, efficacious, and safe therapy against neurodegenerative disorders, it becomes vital to elucidate the cellular and molecular mechanisms that control neuronal and vascular injury. These include the pathways of free radical injury, the independent mechanisms of programmed cell death, and the downstream signal transduction pathways of endonuclease activation, intracellular pH, cysteine proteases, the cell cycle, and tyrosine phosphatase activity. Employing the knowledge gained from investigations into these pathways will hopefully further efforts to successfully develop effective treatments against central nervous system disorders.     

T-cell responses to the trypanosome variant surface glycoprotein: a new paradigm?

During the past decade, extensive knowledge has been gained with respect to the cellular and molecular mechanisms associated with variant surface glycoprotein (VSG) gene switching in trypanosomes. However, comparatively little is known about the cellular and molecular factors that regulate the host B-cell response to VSG determinants during infection. Here, John Mansfield reflects on the nature of this response.     

The regulation of physiological changes during mammalian aging.

Much evidence suggests that intrinsic molecular or cellular aging mechanisms need not be invoked to explain most age-related cellular changes and pathologcical conditions. Analysis of a widely scattered literature indicates that hormones and neural factors regulate a great number of cellular aging phenomena of mammals. It is proposed that age-related changes after maturation result from an extension of the neural and endocrine mechanisms that control earlier development and that produce a regulatory cascade of changing neural, endocrine, and target-tissue interactions.     

Aquaporin 4: A key player in Parkinson's disease

Parkinson's disease (PD) is one of the most prevalent neurodegenerative diseases which occur in aged people worldwide. Given that a sequence of cellular and molecular mechanisms, including oxidative stresses, apoptosis, inflammatory pathways, microglia, astrocyte activation, and aquaporin 4 (AQP4) are associated with initiation and the progression of PD. AQP4 may affect various pathways (i.e., α-synuclein, inflammatory pathways, and microglia and astrocyte activation). Few reports have evaluated the relationship between AQP4 and PD-related cellular and molecular pathways. Here, for the first time, we highlighted the relationship between AQP4 and molecular mechanisms involved in PD pathogenesis.     

How regulators of G protein signaling achieve selective regulation

The regulators of G protein signaling (RGS) are a family of cellular proteins that play an essential regulatory role in G protein-mediated signal transduction. There are multiple RGS subfamilies consisting of over 20 different RGS proteins. They are basically the guanosine triphosphatase (GTPase)-accelerating proteins that specifically interact with G protein alpha subunits. RGS proteins display remarkable selectivity and specificity in their regulation of receptors, ion channels, and other G protein-mediated physiological events. The molecular and cellular mechanisms underlying such selectivity are complex and cooperate at many different levels. Recent research data have provided strong evidence that the spatiotemporal-specific expression of RGS proteins and their target components, as well as the specific protein-protein recognition and interaction through their characteristic structural domains and functional motifs, are determinants for RGS selectivity and specificity. Other molecular mechanisms, such as alternative splicing and scaffold proteins, also significantly contribute to RGS selectivity. To pursue a thorough understanding of the mechanisms of RGS selective regulation will be of great significance for the advancement of our knowledge of molecular and cellular signal transduction.     

Theoretical investigation of the neuronal Na+ channel SCN1A: abnormal gating and epilepsy

Epilepsy is a paroxysmal neurological disorder resulting from abnormal cellular excitability and is a common cause of disability. Recently, some forms of idiopathic epilepsy have been causally related to genetic mutations in neuronal ion channels. To understand disease mechanisms, it is crucial to understand how a gene defect can disrupt channel gating, which in turn can affect complex cellular dynamic processes. We develop a theoretical Markovian model of the neuronal Na+ channel NaV1.1 to explore and explain gating mechanisms underlying cellular excitability and physiological and pathophysiological mechanisms of abnormal neuronal excitability in the context of epilepsy. Genetic epilepsy has been shown to result from both mutations that give rise to a gain of channel function and from those that reduce the Na+ current. These data may suggest that abnormal excitation can result from both hyperexcitability and hypoexcitability, the mechanisms of which are presumably distinct, and as yet elusive. Revelation of the molecular origins will allow for translation into targeted pharmacological interventions that must be developed to treat syndromes resulting from divergent mechanisms. This work represents a first step in developing a comprehensive theoretical model to investigate the molecular mechanisms underlying runaway excitation that cause epilepsy.     

Molecular basis for constructing artificial immunogens

The molecular and cellular mechanisms of the effect of synthetic polyions on immunogenesis are discussed in the paper. The data on the basic properties of polyion immune stimulants and on the mechanisms of cellular reactions to these stimulants were used for constructing artificial antigen-polyion complexes having enhanced immunogenic properties. The vaccinating properties of a number of macromolecular complexes conjugated to bacterial and viral antigens are analyzed.     

Molecular mechanisms of synaptic plasticity and memory.

To unravel the molecular and cellular bases of learning and memory is one of the most ambitious goals of modern science. The progress of recent years has not only brought us closer to understanding the molecular mechanisms underlying stable, long-lasting changes in synaptic strength, but it has also provided further evidence that these mechanisms are required for memory formation.     

肝纤维化发病机制中细胞和分子机制的研究进展

关于肝纤维化形成的复杂的细胞和分子联系已经有了相当多的研究进展。最近的数据表明,纤维化进程的终止和纤维分解途径的恢复可以逆转晚期肝纤维化甚至肝硬化。因此,需要更好地阐明参与肝纤维化的细胞和分子机制。HSC(肝星状细胞)的激活是肝纤维化发生的中心事件,此外还有产生基质的其他细胞来源,包括肝门区的成纤维细胞,纤维细胞和骨髓来源的肌纤维母细胞。这些细胞与其邻近细胞通过多种联系聚集产生纤维疤痕并造成持续性损伤。阐明不同类型的细胞的相互作用,揭示细胞因子对这些细胞的影响,理清活化HSC基因表达的调控,将有助于我们探索新的肝纤维化治疗靶点。此外,不同的病因有不同的致病途径,弄清这一点有助于针对特异性疾病治疗方法的发现。本文概述了肝纤维化的细胞和分子机制的最新研究进展,可能为未来治疗方法带来新的突破。     

Involvement of plant cytoskeleton in cellular mechanisms of metal toxicity

Literature data and results of the studies carried out us concerning the involvement of plant cell cytoskeleton in cellular mechanisms of metal toxicity are summarized. Characteristics of cytotoxic effect of metals on plant cytoskeleton and, in particular, on microtubules and actin filaments are reviewed. Particular attention is paid to cellular and molecular mechanisms of metal impact on cytoskeleton. The most probable binding sites of heavy metals, as well as alternative mechanisms of their impact on cytoskeleton, are discussed.