Genetic evidence that relative synaptic efficacy biases the outcome of synaptic competition

Synaptic activity drives synaptic rearrangement in the vertebrate nervous system; indeed, this appears to be a main way in which experience shapes neural connectivity. One rearrangement that occurs in many parts of the nervous system during early postnatal life is a competitive process called 'synapse elimination'. At the neuromuscular junction, where synapse elimination has been analysed in detail, muscle fibres are initially innervated by multiple axons, then all but one are withdrawn and the 'winner' enlarges. In support of the idea that synapse elimination is activity dependent, it is slowed or speeded when total neuromuscular activity is decreased or increased, respectively. However, most hypotheses about synaptic rearrangement postulate that change depends less on total activity than on the relative activity of the competitors. Intuitively, it seems that the input best able to excite its postsynaptic target would be most likely to win the competition, but some theories and results make other predictions. Here we use a genetic method to selectively inhibit neurotransmission from one of two inputs to a single target cell. We show that more powerful inputs are strongly favoured competitors during synapse elimination.     

The role of neuronal identity in synaptic competition

In developing mammalian muscle, axon branches of several motor neurons co-innervate the same muscle fibre. Competition among them results in the strengthening of one and the withdrawal of the rest. It is not known why one particular axon branch survives or why some competitions resolve sooner than others. Here we show that the fate of axonal branches is strictly related to the identity of the axons with which they compete. When two neurons co-innervate multiple target cells, the losing axon branches in each contest belong to the same neuron and are at nearly the same stage of withdrawal. The axonal arbor of one neuron engages in multiple sets of competitions simultaneously. Each set proceeds at a different rate and heads towards a common outcome based on the identity of the competitor. Competitive vigour at each of these sets of local competitions depends on a globally distributed resource: neurons with larger arborizations are at a competitive disadvantage when confronting neurons with smaller arborizations. An accompanying paper tests the idea that the amount of neurotransmitter released is this global resource.     

Transgenic strategies for combinatorial expression of fluorescent proteins in the nervous system

Detailed analysis of neuronal network architecture requires the development of new methods. Here we present strategies to visualize synaptic circuits by genetically labelling neurons with multiple, distinct colours. In Brainbow transgenes, Cre/lox recombination is used to create a stochastic choice of expression between three or more fluorescent proteins (XFPs). Integration of tandem Brainbow copies in transgenic mice yielded combinatorial XFP expression, and thus many colours, thereby providing a way to distinguish adjacent neurons and visualize other cellular interactions. As a demonstration, we reconstructed hundreds of neighbouring axons and multiple synaptic contacts in one small volume of a cerebellar lobe exhibiting approximately 90 colours. The expression in some lines also allowed us to map glial territories and follow glial cells and neurons over time in vivo. The ability of the Brainbow system to label uniquely many individual cells within a population may facilitate the analysis of neuronal circuitry on a large scale.     

Mature murine B lymphocytes immortalized by Kirsten sarcoma virus

Clonal, antigen-specific, functionally responsive cell populations have proved critical for the analysis of the activation and regulation of lymphocytes. Such studies with B lymphocytes, the precursors of antibody-secreting cells, are hampered by the difficulty in generating phenotypically mature, antigen-reactive lines from defined cell populations. One method is to use acutely transforming retroviruses, which can transform B-lineage lymphocytes in vitro. However, Abelson murine leukaemia virus (A-MuLV) infection of murine bone marrow cells in vitro yields mostly immature B-cell lines, and infection of murine bone marrow cells with murine sarcoma viruses carrying ras related genes produces only immature lymphoid cell lines. Retroviruses which contain ras can immortalize nonlymphoid cells without causing loss of mature phenotypic characteristics. We used ras-containing Kirsten sarcoma virus (KiSV) pseudotyped with an amphotropic MuLV helper virus, to infect a purified population of mature, hapten-binding murine splenic B lymphocytes, aiming to generate mature B-cell lines to use as models for the study of B-cell growth and differentiation physiology. Immortalized B-cell lines which retain the same mature phenotype as the starting population, including hapten-specific binding, were produced. This is the first demonstration of a method for immortalizing selected antigen-binding B lymphocytes, and the first example of immortalization of mature B cells in vitro with an acutely transforming ras-containing retrovirus.