There were significant differences for plant height and stem diameter, between the genotypes assessed through sexual seed (Table 4). Genotypes 22A, 15B, 15C and Castilla showed the highest ΔPH with values between 0.34 and 0.41 cm day^-1 in comparison with the control, indicating that the infection process caused by the fungus within the vascular system of these genotypes, generated a relatively low decrease in apical growth, which may be due to a mild or first-stage infection process corresponding to epidermal fixation or penetration and does not progress to a second stage, which corresponds to intravascular colonization (Gonzales et al., 2012). Similarly, it can be considered that as a mechanism of infection, the pathogen can take two routes, initially hemibiotrophic and then necrotrophic (Perfect and Green, 2001), considering in this case that only the first one occurred.

Table 4

Genotype 42A showed the lowest average ΔPH with 0.14±0.06 cm day^-1 with a more severe intravascular colonization process and affecting the apical growth (Table 5).

Table 5

For ΔSD, no genotype showed a significantly different mean, except for the control that showed a highly significant difference compared to the other genotypes. The ΔSD ranged from 0.001 cm day^-1 for 35A to 0.09 cm day^-1 for 15C, 19A, 22A, 36B, and 42A (Table 5). In 35A and Castilla, the values of ΔSD indicates that the infection process is compromising the normal development of the stem by blocking vascular ducts. According to González et al. (2012), these results showed that exist a colonization of the mycelium into the xylem and the establishment of the fungus in the plant via this tissue. This invasion through the vascular bundles causes symptoms such as dwarfism, wilt, and loss of turgor since nutrient and water transport are affected by the colonization of this pathogen, This coincides with the statements of Chekali et al. (2011) and Cruz et al. (2011), who affirmed that as a typical response to the fungus, metabolic and growth functions are altered in plants and that according to their evolution and aggressiveness, which vary by their age, their susceptibility to the pathogen and environmental conditions, they can even cause their death. The results obtained are also corroborated with similar works carried out by Clavijo (2014), which by means of pathogenicity tests with Fusarium oxysporum in the chili bell pepper crop was demonstrated that in addition to the susceptibility of this crop to the pathogen, it influenced in the growth variables such as height and stem diameter at the end of its evaluation.

For DOS variable, there were highly significant differences between genotypes (Table 4). Among the 22 genotypes, 44% showed a disease incubation period between 7 and 14 days. These results differ from those reported by Manangón et al. (2015), Maya and Lagos (2011) and Narváez and Zambrano (2006), who obtained incubation averages between 21 and 46 days in different accessions of the Lasiocarpa section under controlled conditions and can be explained by the difference in the infective capacity of F. oxysporum isolates and the resistance or susceptibility of the genetic materials evaluated (González et al., 2012).

Genotypes 15C, 36B, HSF1, HSF10, HSF36 and control did not show signs of vascular and root wilt during the trial period (Table 6). However, the intensity of infection caused by F. oxysporum is often visually diagnosed by the typical symptoms of the disease, but it is not proportional with internal infection processes such as vascular colonization and it is necessary to evaluate organs such as root and stem to determine if an infectious process exists (Ríos et al., 2018). To confirm these findings, we re-inoculated with isolates Fo1, Fo2, Fo16, and Fo19 after three months of the assessment; there was not visible disease symptoms, vascular colonization processes or any type of root necrosis.

Table 6

Genotypes 16A, 19A, 42A, HSF7 and HSF25 showed the lowest averages, with the onset of symptoms at seven days post-inoculation (DPI), as demonstrated by chlorotic leaves and loss of turgor. The highest average was obtained by HSF15 with 64.4 DPI, followed by 37B with 42 DPI, and HSF4 with 37.8 DPI (Table 6).

It is worth mentioning that Ortiz (2011) reported incubation periods of 8 to 10 days for plants inoculated with F. oxysporum and subjected to excess water stress in another Solanaceae (Physalis peruviana) and 18 to 24 days for plants also inoculated under normal humidity conditions. These data added to those reported by Clavijo (2014), who found the appearance of symptoms such as yellowing, necrosis and defoliation in about six days after inoculation with the pathogen, suggest variability in the first place, with respect to the environmental influence on the expression of the pathogen and secondly, to the virulence of the inoculated strain. This aspect confirms the importance of the response of the genotypes that were re-inoculated, since their initial behavior did not vary.

Incidences (I) of vascular wilt were between 0 and 100%. Specifically, 77.3% of the genotypes (17 genotypes) showed I of 100% and 22.7% showed 0% incidences (5 genotypes). Genotypes 15C, 36B, HSF1, HSF10 and HSF36 displayed 0% I and S; thus, demonstrating resistance to isolate Fo15 and to the mix of isolates Fo1, Fo2, Fo16 and Fo19. These genotypes could be used in genetic improvement programs, evaluated as parents in different environments to determine their genetic potential and adaptation to the producing areas of the department of Nariño, based on the fact that the progress of these programs is more efficient when there is an adequate characterization of the attributes of interest in a population of a given species (Morillo et al., 2019).

For the control of this disease, numerous practices and activities have been reported that are generally based on the use of agrochemicals with their economic and environmental implications. That is the reason why the genetic improvement of resistance as a form of effective control for this disease has allowed to develop increasingly efficient strategies (García-Velasco et al., 2020). In this regard, it is worth considering that the Fusarium genus, due to its great variability, is one of the most difficult to manage of all fungal groups (Dean et al., 2012). Thus, the use of resistant varieties could reduce the incidence of the disease and for this purpose it is necessary to have genotypes within the species of interest that are favorable in this aspect (Horinouchi et al., 2011). This situation confirms the importance of identifying the genotypes presented here as candidates for genetic improvement programs.

In contrast, genotypes 42A, 35A, 16A, HSF2, HSF7, HSF25 and HSF45 showed I of 100% and S between 72% and 88% (Figures 1 and 2), being highly susceptible to pathogen, with symptoms of generalized chlorosis, necrosis of new leaves, necrosis in main leaves, and loss of turgor. These results are consistent with those obtained by Narváez and Zambrano (2006) and Gallardo (2005), who evaluated different genotypes of S. quitoense and between 9 and 11 week of evaluation reached the highest level of severity in 90% of their seedlings and the remaining 10% presented low levels as chlorosis and flaccidity in the lower leaves. On the other hand, it is also worth mentioning the work of Arizala et al. (2011), who evaluated the response to F. oxysporum of wild species of lulo, in which they highlighted low incidence for Solanum hirtum and Solanum marginatum, the former with physical compatibility in the use of grafts with S. quitoense, which is the reason why, in addition to those mentioned, it is possible to think about interspecific improvement processes for the study area.

Figure 1

Figure 2

Genotypes HSF15 and 15B showed S of 20% and 28%, respectively, with slight chlorosis in new leaves and a slight delay in growth. Also, these genotypes were re-inoculated with the mix of Fo1, Fo2, Fo16, and Fo19 obtaining S of 30% and 33%, finding that the two genotypes survived during the trial period, suggesting tolerance or a resistance mechanism different of the other genotypes. According to Forero et al. (2015), this expression of tolerance can be due to physiological factors, such as an increased concentration of chlorophyll in leaves or an increased number of new leaves or sprouts, which promote the emission and opening of floral buds or increase nutrient uptake. Also, these two genotypes, must be considered for evaluation in different environments to determinate his agronomic potential.

Regarding the growth variables evaluated, genotypes 22A, 15B and 15C stood out for showing the greatest increase in plant height over the susceptible Castilla control, which also, with respect to the increase in stem diameter, showed a lower value than the other genotypes, thus indicating the favorable behavior of the populations evaluated with respect to the presence of the disease.

Based on their differential response and with respect to the other genotypes in terms of periods of observation of symptoms, incidence and severity of the disease, genotypes 15C, 36B, HSF1, HSF10 and HSF36 did not show symptoms related to the inoculation of isolates Fo15 of F. oxysporum and the mixture of four other isolates, even after re-inoculation. This aspect is relevant for the genetic improvement of the species, since these could form the basis of a program based on resistance to Fusarium oxysporum for the department of Nariño, an evaluation that logically should be developed in an integral framework with other variables of productivity and agronomic behavior under cultivation conditions.