Ludmila Lackova

The Annual Biosemiotic Achievement Award was established at the annual meeting of the International Society for Biosemiotic Studies (ISBS) in 2014, in conjunction with Springer and _Biosemiotics_. It seeks to recognize papers published in the journal that present novel and potentially important contributions to biosemiotic research, its scientific impact, and its future prospects. Here the winner of the Biosemiotic Achievement Award for 2022 is announced: The award goes to Sigmund Ongstad for his article “Simple Utterances but Complex Understanding? Meta-studying the Fuzzy Mismatch between Animal Semantic Capacities in Varied Contexts”.

Peirce’s sign model is introduced as incompatible with structural semiology in the majority of semiotics textbooks. In this paper, I would like to argue against this general polarization of the semiotic discipline. I focus on compatibilities between Lucien Tesnière’s syntactic theory (verbal valency) and Peirce’s logic of relatives. My main argument is that structural linguistics is not necessarily dyadic, and that Peirce’s sign doctrine is perfectly structural. To define the structural approach in Peirce, I analyze the notions of form (structure) and substance in Hjelmslev and Peirce. The aim of my argument is to contribute to attempts to introduce Peirce’s theory to the field of linguistics in the hope that such an integration will be beneficiary for general linguistics. To extend and support my argument, I provide some examples from biology where Peirce’s theory has been applied. I demonstrate an analogy between the biological structures of proteins and the structure of a sentence with Peirce’s own writings. I consequently introduce Peirce as the first structural semiologist and as the first biolinguist.

New discoveries in the life sciences have affirmed that the virtual script as well as its context-dependent reading and interpretation determine the final living creature. An extended understanding of Darwinian Theory is crucial for understanding life as semiosis in terms of Peirce and Eco’s semiotic models. The semiosis of living systems is potentially unlimited. Genes are not static and unchangeable scripts, but can always be reinterpreted by new interpretants that illuminate them from different points of view, depending on which properties are relevant in a particular context. The encyclopedia is a term, in Umberto Eco’s semiotics, which represents the multidimensional space of semiosis that is governed by a self-sustaining production of interpretants. The paper will present the idea of understanding the Extended Synthesis in terms of a biosemiotic enyclopedia.

The article deals with the notion of the genetic code and its metaphorical understanding as a “language”. In the traditional view of the language metaphor of the genetic code, combinations of nucleotides are signs of amino acids. Similarly, words combined from letters represent certain meanings. The language metaphor of the genetic code, 171–200, 2011) assumes that the nucleotides stay in the analogy to letters, triples to words and genes to sentences. We propose an application of mathematical linguistic methods on the notion of the genetic code. We provide quantitative analysis of mRNA strings and natural language texts. This analysis is sensitive to the detection of the code units hierarchy. We also take into consideration a representative quantitative analysis of DNA, RNA and proteins. Our analysis of mRNA confirms an assumption that the design of the genetic code cannot analogize DNA bases and letters. The notion of the letter is much more appropriate if analogized with triplets or amino acids, 187–191, 2017).

Metaphors involve immense explanatory power and positive impact predominantly in the scientific education and popularization. Still the use of metaphors in science might be a double-edged sword. Introduction of the computer metaphor to many scientific fields in the last century resulted in reductionist approaches, oversimplifications and mechanistic explanations in science as well as in humanities. In this short commentary we developed further the computer metaphor by prof. Noble and the illusions this metaphor led to in genetics, linguistics and consequently DNA linguistics.

The concept of protosemiosis or semiosis at the lower levels of the living goes back to Giorgio Prodi, Thomas A. Sebeok and others. More recently, a typology of proto-signs was introduced by Sharov and Vehkavaara. Kull uses the term of vegetative semiosis, defined by iconicity, when referring to plants and lower organism semiosis. The criteria for the typology of proto-signs by Sharov and Vehkavaara are mostly based on two important presuppositions: agency and a lack of representation in low-level semiosis. We would like to focus on an alternative approach to protosign classification. In particular, we aim to provide a sign-typological characteristic of proteins (in analogy to Maran’ s classification of environmental signs). Our approach is focused on representation, that is, we only consider the relation between a sign and its object. We are considering representation independently from the role of interpretant and interpretation (which is an epiphenomenon of agency). Two hypotheses are investigated and accordingly evaluated in this paper: (I) Proteins are indexical protosigns. (II) Proteins are iconic protosigns. The conclusion our argumentation leads to supports the hypothesis (II).

In this paper I attempt to study the notion of “folding of a semiotic continuum” in a direction of a possible application to the biological processes. More specifically, the process of obtaining protein structures is compared in this paper to the folding of a semiotic continuum. Consequently, peptide chain is presented as a continuous line potential to be formed in order to create functional units. The functional units are protein structures having certain function in the cell or organism. Moreover, protein folding is analyzed in terms of tension between syntax and semantics.

The present paper attempts to demonstrate semiotic arguments against the sequence → structure → function paradigm in protein studies. The unidirectional deterministic thinking in biological processes has been challenged by several disciplines of life sciences and philosophy. Biosemiotics comprehends living organisms as actively participating in their present and somehow creating or shaping their future, having a plurality of options for acting. Determinism and unidirectionality are in contradiction with a biosemiotic approach towards life, mostly when considering Peirce’s triadic concept of semiosis. In this paper, a Peircean biosemiotic approach is applied to proteins and to the process of protein folding. Two main concepts are presented to support the arguments against the SSF paradigm in protein studies: the NonReduction Theorem and the notion of folded continuum. A processual approach is proposed as the most suitable for descriptions of proteins and their functions.

The present paper attempts to demonstrate semiotic arguments against the sequence → structure → function paradigm in protein studies. The unidirectional deterministic thinking in biological processes has been challenged by several disciplines of life sciences and philosophy. Biosemiotics comprehends living organisms as actively participating in their present and somehow creating or shaping their future, having a plurality of options for acting. Determinism and unidirectionality are in contradiction with a biosemiotic approach towards life, mostly when considering Peirce’s triadic concept of semiosis. In this paper, a Peircean biosemiotic approach is applied to proteins and to the process of protein folding. Two main concepts are presented to support the arguments against the SSF paradigm in protein studies: the NonReduction Theorem and the notion of folded continuum. A processual approach is proposed as the most suitable for descriptions of proteins and their functions.

The present paper attempts to demonstrate semiotic arguments against the sequence → structure → function paradigm in protein studies. The unidirectional deterministic thinking in biological processes has been challenged by several disciplines of life sciences (epigenetics, proteomics, etc.) and philosophy (process philosophy). Biosemiotics comprehends living organisms as actively participating in their present and somehow creating or shaping their future, having a plurality of options for acting. Determinism and unidirectionality are in contradiction with a biosemiotic approach towards life, mostly when considering Peirce’s triadic concept of semiosis. In this paper, a Peircean biosemiotic approach is applied to proteins and to the process of protein folding. Two main concepts are presented to support the arguments against the SSF paradigm in protein studies: the NonReduction Theorem and the notion of folded continuum. A processual approach is proposed as the most suitable for descriptions of proteins and their functions.