Dataset on quality and physiological changes of raspberry fruit during their development and under auxin in-vitro assay

The data presented in this article are related to the research article entitled “Expression of two indole-3-acetic acid (IAA)-amido synthetase (GH3) genes during fruit development of raspberry (Rubus idaeus Heritage)” (Bernales et al., In press). This data article describes the relation of all size variables between them and with the weight showing an increasing trend between length and weight and an inverse relation of fruit firmness and ethylene production during development. In addition, IAA treatment during auxin in-vitro assay showed no significant changes in firmness, a significant increase of ethylene and respiratory production.


a b s t r a c t
The data presented in this article are related to the research article entitled "Expression of two indole-3-acetic acid (IAA)-amido synthetase (GH3) genes during fruit development of raspberry (Rubus idaeus Heritage)" (Bernales et al., In press). This data article describes the relation of all size variables between them and with the weight showing an increasing trend between length and weight and an inverse relation of fruit firmness and ethylene production during development. In addition, IAA treatment during auxin in-vitro assay showed no significant changes in firmness, a significant increase of ethylene and respiratory production.
&  Subject area  Agriculture, biology  More specific subject area Fruit development  Type of data  Table and figures How data was acquired The fruit size and weight were measures using a caliper and analytical balance, respectively. The fruit firmness was measured using the Firm Tech II equipment (BioWorks Inc., Wamego, KS, USA) and data were expressed as Newton (N). Ethylene production was quantified in a gas chromatograph (Shimadzu 8A, Tokyo, Japan) equipped with a flame ionization detector, and the resulting data were expressed as mL ethylene kg À 1 h À 1 . Respiratory production was determined using a CO 2 detector (MAP Head space Gas Analyser, Bridge Analysers, USA), and the resulting data were expressed as mg CO 2 kg À 1 h À 1 .

Data format
Analysed data Experimental factors Data were obtained from different development stages and auxin invitro assay according to Bernales et al. In press [1].

Experimental features
The relation between quality and physiological parameter during raspberry development and significant differences between the treatment of in-vitro assay were determined using R Statistical Software Value of the data These data present information about quality and physiological changes during raspberry development and auxin in-vitro assay.
Data are important considering the factor and timing that determine raspberry quality. These data can be used for estimating the timing and concentration of hormonal treatment for improved fruit quality characteristics.

Data
A high correlation between all growth variables and weight was found ( Table 1). The relation between length and weight variables shows a potential growth until 1.75 cm, and afterwards a less pronounced increment in fruit growth (after the fruits attained 2 g of weight) (Fig. 1A). On the other hand, the ethylene and fruit firmness showed a negative correlation (Table 1, Fig. 1B).
During auxin in-vitro assay, no significant differences of firmness were observed between the indole-3-acetic acid (IAA)-, indole-3-propionic acid (IPA)-treated and control fruit during the times Table 1 Correlation between growth variables and between firmness and ethylene production variables for different developmental and ripening stages of raspberry. Analysis of growth variables included all samples (140 observations with four variables). Correlation between firmness and ethylene production considering every ripening stages of the raspberry fruit. All analyses were done by the Pearson method. Fig. 1. The relation between growth variables: length (cm) and weight (g) (A) and between fruit firmness (N) and ethylene production (mL kg À 1 h À 1 ) variables (B) for different developmental and ripening stages of raspberry were conducted. For growth variables, the relation matches the data presented in Table 1 showing a potential trend. The analysis included all samples (140 observations with four variables). On the other hand, the relation between fruit firmness and ethylene production matches a negative correlation, but with a polynomial fit curve. For both cases, for simplicity, a linear trend could use it. The analysis was considered for every ripening states of the raspberry fruit development. Fig. 2. Physiological and quality parameters of raspberry fruit during auxin treatment. Auxin in-vitro assay was performed on W stage raspberry. (A) Firmness (N), (B) respiration mg CO 2 kg À 1 h À 1 and (C) ethylene production (mL kg À 1 h À 1 ) were determined for IAA and controls samples. IAA: Indol-3-acetic acid; IPA: Indole-3-propionic acid. Data are represented as the means 7 SE from five replicates (each one contains 10 fruits). Significant differences from IAA-to control and IPA-treated fruits at the same time of treatment are indicated by (*) and (**) for the probability levels (P r 0.05) and (P r 0.01), respectively. evaluated ( Fig. 2A). Conversely, respiration was significantly increased at 18 and 36 h by IAA treatment compared to IPA (no active auxin) and control conditions (Fig. 2B). Similarly, ethylene production was also increased at 36 h by IAA treatment (Fig. 2C).

Experimental design, materials, and methods
The quality and physiological assessment were determined during raspberry development and invitro auxin treatment [1]. Size variables and weight data for correlation analysis were obtained from twenty fruits of each developmental stage classified according to size and colour [1,3,4]. Data for auxin in-vitro assay were obtained analysing firmness, ethylene and respiratory production in three groups of treatments [1,5].
The fruit size and weight during raspberry development were measures using a caliper and analytical balance, respectively. Fruit firmness, ethylene production and respiratory production during development and auxin in-vitro assay were determined as described by Bernales et al. [1], and the resulting data were expressed as the mean 7 standard error (SE) of Newton (N), mL of ethylene kg À 1 h À 1 and mg CO 2 kg À 1 h À 1 , respectively. The data obtained during development were correlated by means of Pearson's correlation matrix. An analysis of variance was performed for data obtained from auxin invitro assay, and significant differences were determined at P r 0.05 (*) and P r 0.01 (**) (ANOVA test). All data were analysed using R Statistical Software [2].