Novel Apoplastic Antifreeze Proteins of Deschampsia antarctica as Enhancer of Common Cell Freezing Media for Cryobanking of Genetic Resources, a Preliminary Study.

Antifreeze proteins (AFPs) are natural biomolecules found in cold-adapted organisms that lower the freezing point of water, allowing survival in icy conditions. These proteins have the potential to improve cryopreservation techniques by enhancing the quality of genetic material postthaw. Deschampsia antarctica, a freezing-tolerant plant, possesses AFPs and is a promising candidate for cryopreservation applications. In this study, we investigated the cryoprotective properties of AFPs from D. antarctica extracts on Atlantic salmon spermatozoa. Apoplastic extracts were used to determine ice recrystallization inhibition (IRI), thermal hysteresis (TH) activities and ice crystal morphology. Spermatozoa were cryopreserved using a standard cryoprotectant medium (C+) and three alternative media supplemented with apoplastic extracts. Flow cytometry was employed to measure plasma membrane integrity (PMI) and mitochondrial membrane potential (MMP) postthaw. Results showed that a low concentration of AFPs (0.05 mg/mL) provided significant IRI activity. Apoplastic extracts from D. antarctica demonstrated a cryoprotective effect on salmon spermatozoa, with PMI comparable to the standard medium. Moreover, samples treated with apoplastic extracts exhibited a higher percentage of cells with high MMP. These findings represent the first and preliminary report that suggests that AFPs derived from apoplastic extracts of D. antarctica have the potential to serve as cryoprotectants and could allow the development of novel freezing media.

Preparation of Poly(vinyl Alcohol) Microparticles for Freeze Protection of Sensitive Fruit Crops.

Poly(vinyl alcohol) (PVA) displays ice recrystallization inhibition (IRI) properties as many antifreeze proteins found in cold tolerant organisms. The molecular architecture and composition (molecular weight and distribution of pendant OH and acetate groups) have been studied to improve the antifreezing properties of PVA, suggesting that the molecular architecture of PVA plays an important role in IRI activity. The present work deals with the preparation of PVA microparticles using an alkaline treatment. The effect of PVA molecular weight on the morphology and antifreezeing properties of PVA microparticles was investigated. The antifreezeing property of PVA microparticles on the susceptibility of flower bud tissues to freeze damage was also evaluated. The alkaline treatment of an aqueous PVA solution produced stable polymer chain aggregates with spherical shapes. The average size of the PVA microparticles increased significantly with the increasing molecular weight of the PVA macromolecule precursor. The PVA microparticles inhibited the growth of ice crystals and blocked ice growth at concentrations as low as 0.01 % w/v. The effect of impeding ice crystal growth by preventing the joining of adjacent ice crystals is attributed to the larger size of the PVA particles adsorbed on the ice surface compared to the aggregated PVA macromolecules in saline solution. The thermal hysteresis activity of PVA macromolecules and microparticles was not detected by differential scanning calorimetry analysis. The PVA microparticles reduced the incidence of freeze injuries in flower bud tissues by 55% and their application, considering the low toxicity of PVA, has a high potential for freeze protection in fruit crops.

Effect of in vitro cold acclimation of Deschampsia antarctica on the accumulation of proteins with antifreeze activity.

Deschampsia antarctica has managed to colonize the maritime Antarctic. One of the main factors associated with its tolerance to low temperatures is the presence of apoplastic proteins with antifreeze activity. This work focuses on the effect of cold acclimation of D. antarctica on the accumulation of apoplastic proteins with antifreeze activity. Antifreeze proteins present in apoplastic extracts were purified by ice affinity purification, and their identity was determined by protein sequencing. D. antarctica plants were subjected to 22 days of cold acclimation at 4 °C. The highest content of apoplastic proteins with antifreeze activity was obtained at between 12 and 16 days of acclimation. Protein sequencing allowed their identification with >95% probability. Percentage coverage was 74% with D. antarctica ice recrystallization inhibition protein 1 (DaIRIP1) and 55% with DaIRIP3. Cold acclimation of D. antarctica improved the yield of apoplastic proteins, and resulted in an increase in the antifreeze activity of apoplastic extracts. An in silico analysis suggested that the fluctuations presented by the three-dimensional structures of DaIRIPs help to explain the presence of certain DaIRIPs in apoplastic extracts under the cold acclimation conditions evaluated.

Cold tolerance mechanisms of two arthropods from the Andean Range of Central Chile: Agathemera crassa (Insecta: Agathemeridae) and Euathlus condorito (Arachnida: Theraphosidae).

Two strategies have been described for cold tolerance in arthropods: (1) freeze-tolerant organisms, which can survive the formation of ice crystals and (2) freeze-avoidant organisms, which prevent the ice crystal formation by super cooling their internal fluids. We studied two arthropods from the Andean Range in central Chile (2400 m a.s.l.), the stick insect Agathemera crassa commonly named as "Chinchemolle", and the tarantula spider Euathlus condorito commonly named as "Araña pollito", in order to evaluate how they respond to low temperatures at the physiological and molecular levels. We sampled the soil temperature during one year to track the temperature changes that these organisms must overcome. We found minimum temperatures around -6 °C in autumn, while the temperature were stable at 0 °C in winter due to the snow. The average field-cooling rate was 0.01 ±â€¯0.006 °C min-1. For both arthropods we determined the super cooling point (SCP) at a cooling rate of 1 °C min-1 and its subsequent survival, finding that A. crassa is a freezing tolerant organism with a SCP of -3.8 ±â€¯1.8 °C and 100% survival, while E. condorito is a freezing avoidant organism with a SCP of -3.0 ±â€¯1.3 °C and 0% survival. The SCP and survival were not affected by the season in which individuals were collected, the SCP was significantly affected by the cooling rate of the experiment. Both species had low molecular weight cryoprotective in their hemolymph that could explain their cold-tolerance behavior. Glucose, glycerol, and trehalose were found in A. crassa's hemolymph, only glucose and glycerol were found in E. condorito's. We analyzed the hemolymph proteins and found no seasonal differences in composition for either species and also we detected protein antifreeze activity in the hemolymph from both arthropods.

Draft genome sequences of bacteria isolated from the Deschampsia antarctica phyllosphere.

Genome analyses are being used to characterize plant growth-promoting (PGP) bacteria living in different plant compartiments. In this context, we have recently isolated bacteria from the phyllosphere of an Antarctic plant (Deschampsia antarctica) showing ice recrystallization inhibition (IRI), an activity related to the presence of antifreeze proteins (AFPs). In this study, the draft genomes of six phyllospheric bacteria showing IRI activity were sequenced and annotated according to their functional gene categories. Genome sizes ranged from 5.6 to 6.3 Mbp, and based on sequence analysis of the 16S rRNA genes, five strains were identified as Pseudomonas and one as Janthinobacterium. Interestingly, most strains showed genes associated with PGP traits, such as nutrient uptake (ammonia assimilation, nitrogen fixing, phosphatases, and organic acid production), bioactive metabolites (indole acetic acid and 1-aminocyclopropane-1-carboxylate deaminase), and antimicrobial compounds (hydrogen cyanide and pyoverdine). In relation with IRI activity, a search of putative AFPs using current bioinformatic tools was also carried out. Despite that genes associated with reported AFPs were not found in these genomes, genes connected to ice-nucleation proteins (InaA) were found in all Pseudomonas strains, but not in the Janthinobacterium strain.

De novo DESIGN AND SYNTHESIS OF AN ICE-BINDING, DENDRIMERIC, POLYPEPTIDE BASED ON INSECT ANTIFREEZE PROTEINS / SÍNTESIS Y DISEÑO De novo DE UN POLIPÉPTIDO DENDRÍMERO CON UNIÓN AL HIELO BASADO EN LAS PROTEINAS ANTICONGELANTES DE INSECTOS / Síntes e desenhoo de novo de um polipetídeos dendrímero com uniâo ao gelo baseado nas proteínas anticongelantes de insetos

A new strategy is presented for the design and synthesis of peptides that exhibit ice-binding and antifreeze activity. A pennant-type dendrimer polypeptide scaffoíd combining an a-helical backbone with four short (β-strand branches was synthesized in solid phase using Fmoc chemistry in a divergent approach. The 51-residue dendrimer was characterized by reverse phase high performance liquid chromatography, mass spectrometry and circular dichroism. Each (β-strand branch contained three overlapping TXT amino acid repeats, an ice-binding motif found in the ice-binding face of the spruce budworm (Choristoneura fumiferana) and beetle (Tenebrio molitor) antifreeze proteins. Ice crystals in the presence of the polypeptide monomer displayed fiat, hexagonal plate morphology, similar to that produced by weakly active antifreeze proteins. An oxidized dimeric form of the dendrimer polypeptide also produced fiat hexagonal ice crystals and was capable of inhibiting ice crystal growth upon temperature reduction, a phenomenon termed thermal hysteresis, a defining property of antifreeze proteins. Linkage of the pennant-type dendrimer to a tri-functional cascade-type polypeptide produced a trimeric macromolecule that gave flat hexagonal ice crystals with higher thermal hysteresis activity than the dimer or monomer and an ice crystal burst pattern similar to that produced by samples containing insect antifreeze proteins. This macromolecule was also capable of inhibiting ice recrystallization.

Una nueva estrategia se presenta para el diseño y síntesis de péptidos que se unen al hielo y evidencian actividad anticongelante. Un polipéptido dendrímero del tipo banderín, que combina en su estructura un núcleo a-hélice con cuatro ramificaciones cortas de hojas β, se sintetizó en fase sólida utilizando la química Fmoc con una estrategia divergente. El dendrímero de 51 residuos se caracterizó por cromatografía líquida de alta resolución, espectrometría de masas y dicroís-mo circular. Cada ramifcación de hoja β contiene tres repeticiones de los motivos de aminoácidos TxT sobrelapados, un motivo de unión al hielo presente en la cara de unión de las proteínas anticongelantes del gusano de brotes de abeto (Choristoneura fumiferana) y en el escarabajo (Tenebrio molitor). Los cristales de hielo en presencia del polipéptido monomérico presentan una morfología hexagonal plana, similar a la producida por las proteínas anticongelantes con una débil actividad. Un dímero oxidado del polipéptido también produce cristales de hielo hexagonales planos que fueron capaces de inhibir el crecimiento de los cristales de hielo a medida que se disminuía la temperatura, un fenómeno conocido como histéresis térmica, esto es, una propiedad que define las proteínas anticongelantes. La vinculación del dendrímero tipo banderín a un polipéptido tipo cascada trifuncional produjo una macro-molécula trimérica que generó cristales de hielo hexagonales planos con una mayor actividad de histéresis térmica que los dímeros y los monómeros y un patrón de estallido del cristal de hielo muy similar al producido por las muestras que contienen proteínas anticongelantes de insectos. Estas moléculas además fueron capaces de inhibir la recristianización del hielo.

Uma nova estratégia é apresentada para o desenho e síntese de peptídeos que se unem ao gelo e apresentam atividade anticongelante. Um polipeptídeo dendrímero do tipo pennant que combina em sua estrutura um núcleo a-hélice com quatro ramifcacoes curtas de folhas β foi sintetizado em fase sólida utilizando a química Fmoc com uma estratégia divergente. O dendrímero de 51 resíduos foi caracterizado por cromatografa líquida de alta resolução, espectrometria de massas e dicroísmo circular. Cada ramifcacao de folha (β contém três repeticoes dos motivos de aminoácidos TxT sobrepostos, um motivo de união ao gelo presente na cara de união das proteínas anticongelantes do verme de Choristoneura fumiferana e no escaravelho (Tenebrio molitor). Os cristais de gelo, em presença do polipeptídeo monomérico, apresentam urna morfologia hexagonal plana, similar à produzida pelas proteínas anticongelantes com uma atividade fraca. Um dímero oxidado do polipeptídeo também produz cristais de gelo hexagonais planos e fo-ram capazes de inibir o crescimento dos cristais de gelo à medida que a temperatura diminuia, um fenômeno conhecido como histerese térmica una propriedade que def ne as proteínas anticongelantes. A vinculação do dendrímero tipo pen-nant a um polipeptídeo tipo cascata tri-funcional produziu uma macromolécula trimérica que gerou cristais de gelo hexa-gonais planos com uma maior atividade de histerese térmica que os dímeros e os monómeros e um padrão de estouro do cristal de gelo muito similar ao produzi-do pelas amostras que contêm proteínas anticongelantes de insetos. Estas moléculas, aliás, foram capazes de inibir a recristalização do gelo.