Daily cycles for emission of urticating hairs from the pine processionary caterpillar (Thaumetopoea pityocampa S.) and the brown tail moth (Euproctis chrysorrhoea L) (Lepidoptera) in laboratory conditions

Summary In laboratory conditions, urticating hairs from the pine processionary caterpillar (Thaumetopoea pityocampa S.) and from the brown tail moth (Euproctis chrysorrhoea L.) are detectable in the air using an apparatus designed for the capture of airborne microorganisms and pollen research studies. The hairs produced by the caterpillars of these two species are distributed either via air currents or moths (only forEuproctis). Daily cycles of hair emission were observed and were in relation with locomotion and feeding activities of the caterpillars and with flying and reproductive activities of moths.     

龙葵腺毛发育的细胞学研究

利用光学显微镜、扫描电镜和透射电镜技术,观察了龙葵“四叶一心”期时叶片及茎表皮的腺毛的种类、分布,探究了不同类型腺毛的起源、生长、成熟、分泌、衰老等发育过程的细胞学特征;通过组织化学染色和荧光显微技术,观察了龙葵腺毛成分、分布,为龙葵的进一步开发利用提供参考。结果表明：（1）龙葵腺毛分为单细胞头腺毛和多细胞头腺毛两类,前者主要分布于茎表面和叶上下表皮,后者主要分布于茎表面的单细胞头腺毛之间、叶脉及叶边缘;（2）龙葵腺毛发育起始于表皮细胞突起,单细胞头腺毛行顶端生长,具1-4个柄细胞,四种类型;多细胞头腺毛可再分为一层、两层与三层多细胞头腺毛,另具三种特殊类型;（3）龙葵成熟腺毛具分泌能力,通过皮下空间的物质积累导致腺毛头细胞表面形成突起、包块、破口,最终释放分泌物;而头细胞与柄细胞随即皱缩、衰老。（4）超微结构显示,腺毛头细胞中内质网与高尔基体极为丰富,合成代谢及分泌活动活跃,产生大量包裹嗜锇物质的囊泡,囊泡与细胞壁融合,进而将嗜锇物质转移至细胞壁并积累,随后储存在角质层下的皮下空间直至分泌释放;（5）组织化学染色结果表明,腺毛含有萜类、生物碱、脂类、蛋白质、酚类和多糖。头细胞中主要含有萜类、生物碱、脂类、蛋白质、酚类和中性多糖;柄细胞中主要含有萜类、生物碱、脂类。     

PRODUCTION OF HYALINE HAIRS BY INTERTIDAL SPECIES OF FUCUS (FUCALES) AND THEIR ROLE IN PHOSPHATE UPTAKE1

A field study to determine the precise times of year at which three intertidal species of Fucus start to produce hyaline hairs and cease producing such hairs was conducted on the Isle of Man, U.K. Hairs were first observed during February, and within 6 days of their initial appearance, all tagged plants of all species at all tidal heights on the shore possessed hairs. Hair production continued until the beginning of October, at which time Fucus plants growing at the lowest stations (+ 3.0 m) had glabrous apical growth. Hair production continued later into the year for plants growing higher on the shore, and it was not until mid-November that glabrous apical growth was observed in all plants. Phosphate uptake rates of pilose (hairy) and glabrous (hairless) apical sections were measured in November 1988 for F. spiralis L. and in January 1989 for F. spiralis and F. serratus L., at phosphate concentrations ranging from 0.8 μM (ambient seawater) to 9.0 μM. In ambient seawater, pilose plants of F. spiralis removed phosphate 2–3 times faster than glabrous plants, whereas the uptake rates of pilose plants of F. serratus were about 50% greater than those of glabrous plants. The differences between uptake rates of pilose and glabrous plants of both species were smaller or nonsignificant at higher phosphate concentrations. The field and laboratory data are consistent with the hypothesis that hairs are formed in Fucus as a response to increased nutrient demand and that hairs facilitate the uptake of nutrients from seawater at concentrations typical of natural situations.     

INFLUENCE OF NITROGEN SOURCE ON MORPHOLOGY OF RIVULARIACEAE (CYANOPHYTA)1

Thirty-four heterocyst-producing strains of Rivulariaceae (29 Calothrix, 1 Dichothrix, 2 Gloeotrichia, 2 Rivularia), which produced tapered trichomes in medium minus combined nitrogen, were grown in the presence of nitrate. One strain was unchanged in morphology under this condition. The remaining 33 strains developed trichomes lacking heterocysts. In 19 strains almost all the trichomes became untapered and in the other 14, similar untapered trichomes were produced, but also many tapered trichomes resembling Homoeothrix or Hammatoidea. Similar results were obtained when representative strains were incubated with ammonia as the source of combined N. Only five strains formed colorless hairs in the control medium (minus combined N). The presence of combined N did not diminish hair development in the two strains which had only a few short hairs, but hair frequency and length were both reduced considerably in the three strains with many long hairs in the control medium. Two strains of the non-heterocystous genus Homoeothrix were incubated in medium without combined N. Neither strain showed any growth or heterocyst development, indicating that neither is simply a growth form of a heterocystous genus.     

Ultrastructural and biochemical characterization of the epidermal hairs of the seeds of Cuphea procumbens

Rehydration of desiccated Cuphea seeds results in a rapid morphological change in the seed. Within 20 min thread like epidermal hairs are present on the seed surface. The hairs, which are highly ordered helical structures, are present in the epidermal cells of the desiccated seed. Following emergence the hairs increase in length by means of an eversion process, the mechanism for which is proposed in the text. The hairs were purified to homogeneity and found to be composed of 55% carbohydrate and 45% protein. Following -elimination of the carbohydrate using NaOH/NaBH₄ one major protein of MW 31,000 was seen upon polacrylamide gel electrophoresis in the presence of sodium dodecylsulphate. The protein, here termed helexin, probably plays a major structural role in determining the helical shape of the hairs.     

Barley Root Morphology Affects the Zoospore Production Rate by the Obligate Root Parasite and Soil-borne Virus Vector Polymyxa graminis

Plasmodiophorid parasites in the genus Polymyxa infect roots by means of zoospores and transmit more than 15 soil-borne viruses in a wide range of arable crops. Barley mutants, selected for variations in root hair formation and morphology, were used to demonstrate that root hairs were important but not essential for infection by zoospores of Polymyxa graminis . The relative rates of parasite establishment in roots were determined indirectly as the relative number of zoospores released by roots inoculated with P. graminis in wild-type and mutant plants. The number of P. graminis zoospores released per gram root fresh weight was significantly reduced in brb and rhl1 . b mutants, both of which have no root hairs. This is an important result because there are no natural sources of resistance to P. graminis. Reducing infection levels of viruliferous P. graminis will slow the build up of virus inoculum in the soil and the selection of strains able to overcome the virus resistance in current cereal cultivars.     

Foregut glands of Solenogastres (mollusca): anatomy and revised terminology

In the molluscan class Solenogastres, different types of foregut glands vary in number, structure, and location within the foregut. The present article describes their anatomy and cytology and intends to clarify their confused terminology. Pharyngeal glands, esophageal glands, and the more complex dorsal and ventrolateral foregut glands can be distinguished. The ventrolateral foregut glands (ventral foregut glandular organs, ventral salivary glands of auct.), in the literature subdivided previously into four types, are revisited here in the context of current vertebrate gland terminology. The results of recent investigations are added to earlier ones, and a classification system for these multicellular glands is proposed. This system is based on cytological characters of glandular cells (intra- or extraepithelial), characters of the associated musculature (inner or outer musculature), location of the gland relative to the pharynx epithelium (endoepithelial or exoepithelial), characters of the gland openings (paired or unpaired), morphology of the gland duct (simple or branched), and some additional features like the arrangement of glandular cells along the gland ducts. Gross morphology and anatomy of ventrolateral foregut glands constitute useful taxonomic characters in determining higher taxa (family level), and finer details of the anatomy and cytology are useful in determining lower levels (genus and species). Possible pathways for the evolution of the different gland types of Solenogastres in relation to foregut glands present in the other molluscan clades are presented. The importance of ventrolateral foregut gland characters for phylogenetic considerations within the Solenogastres is discussed.     

Quantitative determination of enhydrin in leaf rinse extracts and in glandular trichomes of Smallanthus sonchifolius (Asteraceae) by reversed-phase high-performance liquid chromatography

A simple, reliable and rapid reversed-phase HPLC-PAD procedure for the characterisation and quantitative determination of the anti-diabetic sesquiterpene lactone enhydrin (1) from Smallanthus sonchifolius (yacón) has been evaluated and validated. The approach focused on the analysis of various leaf rinse extracts, as well as the glandular trichomes of intact leaves, in which 1 was the major compound detected. The best sample preparation of a rinse extract yielded 0.67 mg/mL of 1, whilst a rapid rinse of a small piece of one dried leaf gave 0.09 mg/mL of 1; the highest concentration obtained from a glandular extract was 0.07 mg/mL. The dried leaves of S. sonchifolius were found to contain a total of 0.97% of 1.     

Plant growth and phosphorus accumulation of wild type and two root hair mutants of Arabidopsis thaliana (Brassicaceae)

Arabidopsis thaliana root hairs grow longer and denser in response to low-phosphorus availability. We tested the hypothesis that wild-type Arabidopsis would acquire more phosphorus under phosphorus-limiting conditions than mutants that do not have the root hair response. The growth and phosphorus acquisition of wild-type Arabidopsis (WS) were compared to two root hair mutants (rhd6 and rhd2) under eight phosphorus treatments ranging from 0.4 mmol/m to 54 mmol/m phosphorus. At the lowest phosphorus treatment, all plants were small and showed severe phosphorus stress symptoms. At 1.5 mmol/m phosphorus, WS plants had greater shoot biomass, absolute growth rate, total phosphorus, and specific phosphorus absorption than the two root hair mutants. At the highest phosphorus treatment, there was no difference between genotypes in any of the parameters measured. We conclude that the response of increased root hair growth under low phosphorus availability in Arabidopsis is important in increasing phosphorus acquisition under phosphorus-limiting conditions.