Online research in philosophy

The schematic concept of levels of causal interaction is applied to the relation between genetics and biology. The strength of classical formal genetics lies in its power to proceed directly from observations on an external phenotype, to inferences concerning the nature and properties of the fundamental genetic factors. Its weakness comes from the fact that by short-circuiting the causal chain leading from genotype to phenotype, it creates a divorce between genetics and biology. It is argued that in order to reestablish an articulation of genetics and the biology of whole organisms, it will be necessary to study in detail the entire causal chain leading from a difference in a genetic factor to a difference in a corresponding phenotypic character. This proposal is illustrated by a consideration of multifactorial diseases, which appear to be due to strong interactions between a moderate number of distinct loci; the frequency of abnormal alleles at any given locus may be surprisingly high.

A general case about the insights and oversights of molecular genetics is argued for by considering two specific cases: the first concerns the bearing of molecular genetics on Mendelian genetics, and the second concerns the bearing of molecular genetics on the replicability of the genetic material. As in the first case, it is argued that Mendel's law of segregation cannot be explained wholly in terms of molecular genetics--the law demands evolutionary scrutiny as well. In the second case, it is argued that an account of the replicability of the genetic material in terms of molecular genetics is not entirely independent of evolutionary considerations, in the sense that it raises further evolutionary questions. The limitations of the molecular-genetic approach in these cases point to the limitations of that approach in general.

Within the context of the study of the genetics of language, Chomskian laws of grammar, such as theStructure-dependence Condition and theA over A Condition, may be usefully regarded to have a status similar to that of Mendelian Laws in classical genetics. In both the case of Chomsky's Laws and Mendel's Laws, formal genetic principles are postulated which abstract away from the physical mechanisms involved and in both cases certain apparent counterexamples mirror a more complex underlying genetic organisation.

Population genetics attempts to measure the influence of the causes of evolution, viz., mutation, migration, natural selection, and random genetic drift, by understanding the way those causes change the genetics of populations. But how does it accomplish this goal? After a short introduction, we begin in section (2) with a brief historical outline of the origins of population genetics. In section (3), we sketch the model theoretic structure of population genetics, providing the flavor of the ways in which population genetics theory might be understood as incorporating causes. In sections (4) and (5) we discuss two specific problems concerning the relationship between population genetics and evolutionary causes, viz., the problem of conceptually distinguishing natural selection from random genetic drift, and the problem of interpreting fitness. In section (6), we briefly discuss the methodology and key epistemological problems faced by population geneticists in uncovering the causes of evolution. Section (7) of the essay contains concluding remarks.

are often used loosely – especially in medical contexts. In an attempt to remedy this, these terms are explored from the standpoints of: philosophy of science, medicine, genetics, history of genetics and clinical genetics. A sense for ‘reductionism’ is developed in part by focusing on the related histories of classical genetics and clinical genetics. This done, the dichotomy between holism and reductionism, whether in basic genetics or the genetic counseling situation, loses much of its force. CiteULike Connotea Del.icio.us What's this?

The study of mental illness by the methods of molecular genetics is still in its infancy, but the use of genetic markers in psychiatry may potentially lead to a Virchowian revolution in the conception of mental illness. Genetic markers may define novel clusters of patients having diverse clinical presentations but sharing a common genetic and mechanistic basis. Such clusters may differ radically from the conventional classification schemes of psychiatric illness. However, the reduction of even relatively simple Mendelian phenomena to molecular genetics has been shown to be a surprisingly complex and problematic enterprise. Mental illnesses exist at many levels of including social, environmental, and developmental interactions. Reductionistic shifts in the classification of such a disease entity will have to address the interlevel dynamics that take place within the structure of theories of mental illness. The question of how molecular analysis of psychiatric disease will impact on the structure of existing theories and classification systems is the central topic of this paper. Keywords: disease, philosophy of biology, psychiatry, reductionism CiteULike Connotea Del.icio.us What's this?

The production of genetic knowledge -- Scientific and economic strength of genetic reductionism -- Policy implications : discourses of genetic enlightenment as new disciplinary devices -- Genetic conceptualizations of normality and the idea of genetic justice -- Beyond genetic universality and authenticity, the lure of the genetic underclass -- Previews of the future as background -- Economic and actuarial perspective on genetics and insurance -- Practical and normative arguments against genetic exceptionalist legislation -- The changing social role of private insurance : risk as a new representational regime.

The discussion of theory reduction in genetics threatens to become more and more confused. The position taken is that before one tries to work out complicated reduction principles which might be applicable to broad areas of biology in their relationships to chemistry and physics, it would be better to attempt first to elucidate the internal structure of some limited biological theories in a formal way and to consider simple constructs for reduction between them. This proposal is elaborated with respect to the original Mendelian genetics, linkage genetics and fine-structure genetics, and their relationship to non-formalized molecular genetics.

We present a reconstruction of so-called classical, formal or Mendelian genetics using a notation which we believe is more legible than that of earlier accounts, and lends itself easily to computer implementation, for instance in PROLOG. By drawing from, and emending, earlier work of Balzer and Dawe (1986,1997), the present account presents the three most important lines of development of classical genetics: the so-called Mendel's laws, linkage genetics and gene mapping, in the form of a theory-net. This shows that the set theoretic representation format used in the structuralist approach to the philosophy of science also applies to the domain of genetic theories. There construction is intended to lend more clarity to theme thodological, philosophical and didactical discussions of the foundations of genetics, and on the other hand to defend a formally, logically minded view of theories which seems to have become contested through the work of Feyerabend, Kuhn and Kitcher.