Ribosome-Inactivating Proteins (RIPs) are enzymes that trigger the catalytic inactivation of ribosomes and other substrates. They are present in a large number of plants and have been found also in fungi, algae and bacteria. RIPs are currently classified as type 1, those formed by a single polypeptide chain with the enzymatic activity, and type 2, those formed by 2 types of chains, i.e. A chains equivalent to a type 1 RIPs and B chains with lectin activity. Type 2 RIPs usually contain the formulae A-B, (A-B)2 and less frequent (A-B)4 and polymeric forms of type 2 RIPs lectins. RIPs are broadly distributed in plants, and are present also in fungi, bacteria, at least in one alga; recently RIP-type activity has been described in mammalian tissues. The highest number of RIPs has been found in Caryophyllaceae, Sambucaceae, Cucurbitaceae, Euphorbiaceae, Phytolaccaceae and Poaceae. However there are no systematic screening studies to allow generalisations about occurrence. The most known activity of RIPs is the translational inhibitory activity, which seems a consequence of a N-glycosidase on the 28 S rRNA of the eukaryotic ribosome that triggers the split of the A(4324) (or an equivalent base in other ribosomes), which is key for translation. This activity seems to be part of a general adenine polynucleotide glycosylase able to act on several substrates other than ribosomes, such as tRNA, mRNA, viral RNA and DNA. Other enzymatic activities found in RIPs are lipase, chitinase and superoxide dismutase. RIPs are phylogenetically related. In general RIPs from close families share good amino acid homologies. Type 1 RIPs and the A chains of type 2 RIPs from Magnoliopsida (dicotyledons) are closely related. RIPs from Liliopsida (monocotyledons) are at the same time closely related and distant from Magnoliopsida. Concerning the biological roles played by RIPs there are several hypotheses, but the current belief is that they could play significant roles in the antipathogenic (viruses and fungi), stress and senescence responses. In addition, roles as antifeedant and storage proteins have been also proposed. Future research will approach the potential biological roles played by RIPs and their use as toxic effectors in the construction of immunotoxins and conjugates for target therapy.
ABSTRACT. Although significant progress has been made in the area of injectable hydrogels for biomedical applications and model cell niches, further improvements are still needed, especially in terms of mechanical performance, stability and biomimicry of the native fibrillar architecture found in the extracellular matrix (ECM). This work focuses on the design and production of a silk-elastin-based injectable multiblock co-recombinamer that spontaneously forms a stable physical nanofibrillar hydrogel under physiological conditions. That differs from previously reported silk-elastin-like polymers on a major content and predominance of the elastin-like part, as well as a more complex structure and behavior of such part of the molecule, which is aimed to obtain well defined hydrogels.Rheological and DSC experiments showed that this system displays a coordinated and concomitant dual gelation mechanism. In a first stage, a rapid, thermally driven gelation of the co-recombinamer solution takes place once the system reaches body temperature due to the thermal responsiveness of the elastinlike (EL) parts and the amphiphilic multiblock design of the co-recombinamer. A bridged micellar 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 2 structure is the dominant microscopic feature of this stage, as demonstrated by AFM and TEM.Completion of the initial stage triggers the second, which comprises a stabilization, reinforcement, and microstructuring of the gel. FTIR analysis shows that these events involve the formation of β-sheets around the silk motifs. The emergence of such β-sheet structures leads to the spontaneous selforganization of the gel into the final fibrous structure. Despite the absence of biological cues, here we set the basis of the minimal structure that is able to display such a set of physical properties and undergo microscopic transformation from a solution to a fibrous hydrogel. The results point to the potential of this system as a basis for the development of injectable fibrillar biomaterial platforms towards a fully functional, biomimetic, artificial extracellular matrix and cell niches.
Genetic engineering techniques were used to design and biosynthesise an extracellular matrix (ECM) analogue. This was designed with a well-defined molecular architecture comprising different functional domains. The structural base is a elastin-derived repeating unit, which confers an adequate elastic characteristic. Some of these elastin domains have been modified to contain lysine; this amino acid can be used for crosslinking purposes. The polymer also contain periodically spaced fibronectin CS5 domains enclosing the well-known cell attachment sequence REDV. Finally, the polymer has target sequences for proteolitic action. These sequences are those found in the natural elastin and are introduced to help in the bioabsorption of the polymer. In addition, these proteolitic sequences were chosen in a way that, after proteolitic action, the released fragments will be bioactive. These fragments are expected to promote cell proliferation activity, angiogenesis and other bioactivities of interest for tissue growing, repairing and healing. After purification, the resulting polymers proved to be of high purity and correct sequence. Glutaraldehyde has shown to be a cross-linking agent for this polymer, yielding insoluble hydrogel matrices. This work is framed in a long term project aimed to exploit the power of genetic engineering for the design and bioproduction of complex ECM analogues showing the rich complexity and multi (bio)functionality of the natural matrix.
This work explores the dependence of the inverse temperature transition of elastin-like polymers (ELPs) on the amino-acid sequence, i.e., the amino-acid arrangement along the macromolecule and the resulting linear distribution of the physical properties (mainly polarity) derived from it. The hypothesis of this work is that, in addition to mean polarity and molecular mass, the given amino-acid sequence, or its equivalent--the way in which polarity is arranged along the molecule--is also relevant for determining the transition temperature and the latent heat of that transition. To test this hypothesis, a set of linear and di- and triblock ELP copolymers were designed and produced as recombinant proteins. The absolute sequence control provided by recombinant technologies allows the effect of the amino-acid arrangement to be isolated while keeping the molecular mass or mean polarity under strict control. The selected block copolymers were made of two different ELPs: one exhibiting temperature and pH responsiveness, and one exhibiting temperature responsiveness only. By changing the arrangement and length of the blocks while keeping other parameters, such as the molecular mass or mean polarity, constant, we were able to show that the sequence plays a key role in the smart behavior of ELPs.
The pH-responsive elastin-like polymers, [(PGVGV) 2-(PGEGV)-(PGVGV)2]n with n ) 5, 9, 15, 30, 45, were obtained using genetic engineering and microbial protein expression. These were intended to study the effects of the molecular weight (MW) on the properties of their inverse temperature transition (ITT) and its dependence on pH. As a result, the transition temperature decreased and the transition enthalpy increased as the molecular weight increased, especially for the lowest MWs. More strikingly, the apparent pK a for the γ-carboxyl residue of the glutamic acid also depends on MW. The apparent pKa is lower for lower MWs. In summary, the modification in the ITT caused by changes in MW is similar to the one caused by changes in the mean polarity of the polymer as described in the literature. A reduction in the molecular weight is equivalent to a decrease in the mean hydrophobicity of the polymer.
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